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Transcript 
Clinical
Infectious Diseases Advance Access published August 10, 2016
Clinical Infectious
Diseases
IDSA GUIDELINE
Official American Thoracic Society/Centers for Disease
Control and Prevention/Infectious Diseases Society of
America Clinical Practice Guidelines: Treatment of
Drug-Susceptible Tuberculosis
Payam Nahid,1 Susan E. Dorman,2 Narges Alipanah,1 Pennan M. Barry,3 Jan L. Brozek,4 Adithya Cattamanchi,1 Lelia H. Chaisson,1 Richard E. Chaisson,2
Charles L. Daley,5 Malgosia Grzemska,6 Julie M. Higashi,7 Christine S. Ho,8 Philip C. Hopewell,1 Salmaan A. Keshavjee,9 Christian Lienhardt,6
Richard Menzies,10 Cynthia Merrifield,1 Masahiro Narita,12 Rick O’Brien,13 Charles A. Peloquin,14 Ann Raftery,1 Jussi Saukkonen,15 H. Simon Schaaf,16
Giovanni Sotgiu,17 Jeffrey R. Starke,18 Giovanni Battista Migliori,11 and Andrew Vernon8
1
University of California, San Francisco; 2Johns Hopkins University, Baltimore, Maryland; 3California Department of Public Health, Richmond; 4McMaster University, Hamilton, Ontario, Canada;
National Jewish Health, Denver, Colorado; 6World Health Organization, Geneva, Switzerland; 7Tuberculosis Control Section, San Francisco Department of Public Health, California; 8Division of
Tuberculosis Elimination, National Center for HIV/AIDS, Viral Hepatitis, STD, and TB Prevention, Centers for Disease Control and Prevention, Atlanta, Georgia; 9Harvard Medical School, Boston,
Massachusetts; 10McGill University, Montreal, Quebec, Canada; 11WHO Collaborating Centre for TB and Lung Diseases, Fondazione S. Maugeri Care and Research Institute, Tradate, Italy;
12
Tuberculosis Control Program, Seattle and King County Public Health, and University of Washington, Seattle; 13Ethics Advisory Group, International Union Against TB and Lung Disease, Paris, France;
14
University of Florida, Gainesville; 15Boston University, Massachusetts; 16Department of Paediatrics and Child Health, Stellenbosch University, Cape Town, South Africa; 17University of Sassari, Italy;
and 18Baylor College of Medicine, Houston, Texas
5
Received 4 June 2016; accepted 6 June 2016.
These guidelines were endorsed by the European Respiratory Society (ERS) and the US National Tuberculosis Controllers Association (NTCA). It is important to realize that guidelines cannot always account for individual variation among patients. They are not intended to supplant
physician judgment with respect to particular patients or special clinical situations. The sponsoring and endorsing societies consider adherence to these guidelines to be voluntary, with the
ultimate determination regarding their application to be made by the physician in the light of
each patient’s individual circumstances.
Correspondence: P. Nahid, University of California, San Francisco, San Francisco General Hospital, Pulmonary and Critical Care Medicine, 1001 Potrero Ave, 5K1, San Francisco, CA 94110
( [email protected]).
Clinical Infectious Diseases®
© The Author 2016. Published by Oxford University Press for the Infectious Diseases Society
of America. All rights reserved. For permissions, e-mail [email protected].
DOI: 10.1093/cid/ciw376
EXECUTIVE SUMMARY
The American Thoracic Society (ATS), Centers for Disease Control and Prevention (CDC), and Infectious Diseases Society of
America (IDSA) jointly sponsored the development of this
guideline on the treatment of drug-susceptible tuberculosis,
which is also endorsed by the European Respiratory Society
(ERS) and the US National Tuberculosis Controllers Association
(NTCA). This guideline provides recommendations on the clinical and public health management of tuberculosis in children
and adults in settings in which mycobacterial cultures, molecular
ATS/CDC/IDSA Clinical Practice Guidelines for Drug-Susceptible TB
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The American Thoracic Society, Centers for Disease Control and Prevention, and Infectious Diseases Society of America jointly
sponsored the development of this guideline for the treatment of drug-susceptible tuberculosis, which is also endorsed by the European Respiratory Society and the US National Tuberculosis Controllers Association. Representatives from the American Academy
of Pediatrics, the Canadian Thoracic Society, the International Union Against Tuberculosis and Lung Disease, and the World Health
Organization also participated in the development of the guideline. This guideline provides recommendations on the clinical and
public health management of tuberculosis in children and adults in settings in which mycobacterial cultures, molecular and phenotypic drug susceptibility tests, and radiographic studies, among other diagnostic tools, are available on a routine basis. For all
recommendations, literature reviews were performed, followed by discussion by an expert committee according to the Grading of
Recommendations, Assessment, Development and Evaluation methodology. Given the public health implications of prompt diagnosis and effective management of tuberculosis, empiric multidrug treatment is initiated in almost all situations in which active
tuberculosis is suspected. Additional characteristics such as presence of comorbidities, severity of disease, and response to treatment
influence management decisions. Specific recommendations on the use of case management strategies (including directly observed
therapy), regimen and dosing selection in adults and children (daily vs intermittent), treatment of tuberculosis in the presence of
HIV infection (duration of tuberculosis treatment and timing of initiation of antiretroviral therapy), as well as treatment of extrapulmonary disease (central nervous system, pericardial among other sites) are provided. The development of more potent and bettertolerated drug regimens, optimization of drug exposure for the component drugs, optimal management of tuberculosis in special
populations, identification of accurate biomarkers of treatment effect, and the assessment of new strategies for implementing regimens in the field remain key priority areas for research. See the full-text online version of the document for detailed discussion of the
management of tuberculosis and recommendations for practice.
Keywords. Mycobacterium tuberculosis; HIV infections; antitubercular agents; case management; public health.
Table 1.
Interpretation of “Strong” and “Conditional” Grading of Recommendations Assessment, Development, and Evaluation-Based Recommendations
Implications
for:
Strong Recommendation
Conditional Recommendation
Patients
Most individuals in this situation would want the recommended course
of action, and only a small proportion would not.
The majority of individuals in this situation would want the suggested
course of action, but many would not.
Clinicians
Most individuals should receive the intervention. Adherence to this
recommendation according to the guideline could be used as a
quality criterion or performance indicator. Formal decision aids are
not likely to be needed to help individuals make decisions consistent
with their values and preferences.
Recognize that different choices will be appropriate for individual
patients and that you must help each patient arrive at a management
decision consistent with his or her values and preferences. Decision
aids may be useful in helping individuals to make decisions
consistent with their values and preferences.
Policy
The recommendation can be adopted as policy in most situations.
Policymaking will require substantial debate and involvement of various
stakeholders.
Source: Grading of Recommendations Assessment, Development and Evaluation Working Group [1, 2].
OBJECTIVES OF ANTITUBERCULOSIS THERAPY
Treatment of tuberculosis is focused on both curing the individual patient and minimizing the transmission of Mycobacterium
tuberculosis to other persons, thus, successful treatment of tuberculosis has benefits both for the individual patient and the
community in which the patient resides.
The objectives of tuberculosis therapy are (1) to rapidly reduce the number of actively growing bacilli in the patient, thereby decreasing severity of the disease, preventing death and
halting transmission of M. tuberculosis; (2) to eradicate populations of persisting bacilli in order to achieve durable cure ( prevent relapse) after completion of therapy; and (3) to prevent
acquisition of drug resistance during therapy.
The decision to initiate combination chemotherapy for tuberculosis is based on clinical, radiographic, laboratory, patient,
and public health factors (Figure 1). In addition, clinical judgment and the index of suspicion for tuberculosis are critical in
making a decision to initiate treatment. For example, in patients
(children and adults) who, based on these considerations, have
a high likelihood of having tuberculosis or are seriously ill with
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Nahid et al
a disorder suspicious for tuberculosis, empiric treatment with a
4-drug regimen (Tables 2 and 3) should be initiated promptly
even before the results of acid-fast bacilli (AFB) smear microscopy, molecular tests, and mycobacterial culture are known.
Sixty-five years of investigation, including many clinical trials, have consistently supported the necessity of treating with
multiple drugs to achieve these treatment objectives, minimize
drug toxicity, and maximize the likelihood of treatment completion [3, 4]. The success of drug treatment, however, depends
upon many factors, and numerous studies have found an increased risk of relapse among patients with signs of more extensive disease (ie, cavitation or more extensive disease on chest
radiograph) [5–9], and/or slower response to treatment (ie, delayed culture conversion at 2–3 months) [4, 6, 10, 11].
ORGANIZATION AND SUPERVISION OF TREATMENT
Because of the public health implications of prompt diagnosis and
effective treatment of tuberculosis, most low-incidence countries
designate a government public health agency as legal authority for
controlling tuberculosis [12, 13]. The optimal organization of tuberculosis treatment often requires the coordination of public and
private sectors [14–16]. In most settings, a patient is assigned a
public health case manager who assesses needs and barriers that
may interfere with treatment adherence [17]. With active input
from the patient and healthcare providers, the case manager, together with the patient, develops an individualized “case management plan” with interventions to address the identified needs and
barriers [18–20] (see PICO Question 1 and Supplementary Appendix B, Evidence Profiles 1–3). The least restrictive public
health interventions that are effective are used to achieve adherence, thereby balancing the rights of the patient and public safety.
Given that tuberculosis treatment requires multiple drugs be given
for several months, it is crucial that the patient be involved in a
meaningful way in making decisions concerning treatment supervision and overall care. International standards have been developed that also emphasize the importance of using patientcentered approaches to the management of tuberculosis [14–16].
Key considerations when developing a case management plan
include (1) improving “treatment literacy” by educating the
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and phenotypic drug susceptibility tests, and radiographic studies, among other diagnostic tools, are available on a routine basis.
Nine PICO (population, intervention, comparators, outcomes)
questions and associated recommendations, developed based
on the evidence that was appraised using GRADE (Grading of
Recommendations Assessment, Development, and Evaluation)
methodology [1, 2], are summarized below. A carefully selected
panel of experts, screened for conflicts of interest, including specialists in pulmonary medicine, infectious diseases, pharmacokinetics, pediatrics, primary care, public health, and systematic
review methodology were assembled and used GRADE methods
to assess the certainty in the evidence (also known as the quality
of evidence) and strength of the recommendations (see Supplementary Appendix A: Methods and Table 1). This executive
summary is a condensed version of the panel’s recommendations. Additional detailed discussion of the management of pulmonary and extrapulmonary tuberculosis is available in the fulltext version of this guideline.
patient about tuberculosis and its treatment, including possible
adverse effects [21, 22]; (2) discussing expected outcomes of treatment, specifically the ability to cure the patient of the disease; (3)
reviewing methods of adherence support and plans for assessing
response to therapy; and (4) discussing infectiousness and infection control measures using terminology that is appropriate to
the culture, language, age, and reading level of the patient [23].
For non-English-speaking patients, the use of medical interpreter
services is preferred over using family or friends as interpreters
[24]. Relevant information should be reinforced at each visit.
Other components of the case management plan include, but
are not limited to, setting up patient reminders and systems to
follow-up missed appointments [23, 25–29], use of incentives
and enablers [30, 31], field and home visits [32], and integration
and coordination of tuberculosis care with the patient’s primary
and specialty care (including mental health services, if appropriate and requested by the patient) (Table 4).
PICO Question 1: Does adding case management interventions to
curative therapy improve outcomes compared to curative therapy
alone among patients with tuberculosis? (Case management is
defined as patient education/counseling, field/home visits,
integration/coordination of care with specialists and medical home,
patient reminders, and incentives/enablers).
Recommendation 1: We suggest using case management
interventions during treatment of patients with tuberculosis
(conditional recommendation; very low certainty in the evidence).
Given the critical importance of chemotherapy, both to the
patient and to the public, approaches to ensuring adherence
to the treatment regimen are a major focus of the overall management plan. To maximize completion of therapy, management strategies should utilize a broad range of approaches
(see “Patient-Centered Care and Case Management” in the
full-text version of the guideline). Among these, directly observed therapy (DOT), the practice of observing the patient
swallow their antituberculosis medications, has been widely
used as the standard of practice in many tuberculosis programs,
and deserves special emphasis (see PICO Question 2 and Supplementary Appendix B, Evidence Profile 4). The systematic review conducted to obtain evidence in support of this practice
guideline did not find any significant differences between selfadministered therapy (SAT) and DOT when assessing several
outcomes of interest, including mortality, treatment completion, and relapse. However, DOT was significantly associated
with improved treatment success (the sum of patients cured
and patients completing treatment) and with increased sputum
smear conversion during treatment, as compared to SAT. Because DOT is a multifaceted public health intervention that is
not amenable to the conventional clinical trial approaches to assessing benefits, and because participation in DOT can be advantageous for early recognition of adverse drug reactions and
treatment irregularities, for allowing providers to establish
ATS/CDC/IDSA Clinical Practice Guidelines for Drug-Susceptible TB
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Figure 1. Factors to be considered in deciding to initiate treatment empirically for active tuberculosis (TB) ( prior to microbiologic confirmation). Abbreviations: AFB, acid-fast
bacilli; HIV, human immunodeficiency virus; IGRA, interferon-γ release assay; Mtb, Mycobacterium tuberculosis; TNF, tumor necrosis factor; TST, tuberculin skin test.
Table 2.
Drug Regimens for Microbiologically Confirmed Pulmonary Tuberculosis Caused by Drug-Susceptible Organisms
Intensive Phase
Interval and Doseb
(Minimum Duration)
Continuation Phase
Interval and Doseb,
c
(Minimum
Duration)
Range of
Total
Doses
Druga
1
INH
RIF
PZA
EMB
7 d/wk for 56 doses
(8 wk), or
5 d/wk for 40 doses
(8 wk)
INH
RIF
7 d/wk for 126
doses (18 wk),
or
5 d/wk for 90
doses (18 wk)
182–130
This is the preferred regimen for patients with newly
diagnosed pulmonary tuberculosis.
2
INH
RIF
PZA
EMB
7 d/wk for 56 doses
(8 wk), or
5 d/wk for 40 doses
(8 wk)
INH
RIF
3 times weekly for
54 doses (18
wk)
110–94
Preferred alternative regimen in situations in which
more frequent DOT during continuation phase is
difficult to achieve.
3
INH
RIF
PZA
EMB
3 times weekly for 24
doses (8 wk)
INH
RIF
3 times weekly for
54 doses (18
wk)
78
Use regimen with caution in patients with HIV and/or
cavitary disease. Missed doses can lead to
treatment failure, relapse, and acquired drug
resistance.
4
INH
RIF
PZA
EMB
7 d/wk for 14 doses
then twice weekly
for 12 dosese
INH
RIF
Twice weekly for
36 doses (18
wk)
62
Do not use twice-weekly regimens in HIV-infected
patients or patients with smear-positive and/or
cavitary disease. If doses are missed, then
therapy is equivalent to once weekly, which is
inferior.
Drugs
Commentsc,d
Regimen
Effectiveness
Greater
Lesser
Abbreviations: DOT, directly observed therapy; EMB, ethambutol; HIV, human immunodeficiency virus; INH, isoniazid; PZA, pyrazinamide; RIF, rifampin.
Other combinations may be appropriate in certain circumstances; additional details are provided in the section “Recommended Treatment Regimens.”
a
b
When DOT is used, drugs may be given 5 days per week and the necessary number of doses adjusted accordingly. Although there are no studies that compare 5 with 7 daily doses, extensive
experience indicates this would be an effective practice. DOT should be used when drugs are administered <7 days per week.
c
Based on expert opinion, patients with cavitation on initial chest radiograph and positive cultures at completion of 2 months of therapy should receive a 7-month (31-week) continuation phase.
d
Pyridoxine (vitamin B6), 25–50 mg/day, is given with INH to all persons at risk of neuropathy (eg, pregnant women; breastfeeding infants; persons with HIV; patients with diabetes, alcoholism,
malnutrition, or chronic renal failure; or patients with advanced age). For patients with peripheral neuropathy, experts recommend increasing pyridoxine dose to 100 mg/day.
e
See [426]. Alternatively, some US tuberculosis control programs have administered intensive-phase regimens 5 days per week for 15 doses (3 weeks), then twice weekly for 12 doses.
rapport with the patient and for addressing treatment complications expeditiously, DOT remains the standard of practice in
the majority of tuberculosis programs in the United States [33–
35] and Europe [15] (Table 5). To be consistent with the principles of patient-centered care noted previously, decisions regarding the use of DOT must be made in concert with the
patient [14–16]. For example, DOT can be provided in the office, clinic, or in the “field” ( patient’s home, place of employment, school, or any other site that is mutually agreeable) by
appropriately trained personnel [32].
PICO Question 2: Does self-administered therapy (SAT) have similar
outcomes compared to directly observed therapy (DOT) in patients
with various forms of tuberculosis?
Recommendation 2: We suggest using DOT rather than SAT for
routine treatment of patients with all forms of tuberculosis
(conditional recommendation; low certainty in the evidence).
RECOMMENDED TREATMENT REGIMENS
The preferred regimen for treating adults with tuberculosis
caused by organisms that are not known or suspected to be
drug resistant is a regimen consisting of an intensive phase of
2 months of isoniazid (INH), rifampin (RIF), pyrazinamide
(PZA), and ethambutol (EMB) followed by a continuation
phase of 4 months of INH and RIF (see Tables 2, 3, 10, 11,
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and Supplementary Appendix C) [3, 36, 37]. The intensive
phase of treatment consists of 4 drugs (INH, RIF, PZA, EMB)
because of the current proportion of new tuberculosis cases
worldwide caused by organisms that are resistant to INH [38–
41]; however, if therapy is being initiated after drug susceptibility test results are known and the patient’s isolate is susceptible
to both INH and RIF, EMB is not necessary, and the intensive
phase can consist of INH, RIF, and PZA only. EMB can be discontinued as soon as the results of drug susceptibility studies
demonstrate that the isolate is susceptible to INH and RIF. Pyridoxine (vitamin B6) is given with INH to all persons at risk of
neuropathy (eg, pregnant women; breastfeeding infants; persons infected with human immunodeficiency virus [HIV]; patients with diabetes, alcoholism, malnutrition, or chronic renal
failure; or those who are of advanced age) [42, 43].
With respect to administration schedule, the preferred frequency is once daily for both the intensive and continuation
phases (see PICO Questions 3 and 4 and Supplementary Appendix B, Evidence Profiles 5–11). Although administration of
antituberculosis drugs using DOT 5 days a week has been reported in a large number of studies, it has not been compared
with 7-day administration in a clinical trial. Nonetheless, on the
basis of substantial clinical experience, experts believe that
5-days-a-week drug administration by DOT is an acceptable
alternative to 7-days-a-week administration, and either approach
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Regimen
Table 3.
Dosesa of Antituberculosis Drugs for Adults and Childrenb
Drug
Preparation
Population
Daily
Once-Weekly
Twice-Weekly
Thrice-Weekly
15 mg/kg (typically
900 mg)
15 mg/kg (typically
900 mg)
First-line drugs
Isoniazid
Tablets (50 mg, 100 mg, 300 mg); elixir (50
mg/5 mL); aqueous solution (100 mg/mL)
for intravenous or intramuscular injection.
Note: Pyridoxine (vitamin B6), 25–50 mg/
day, is given with INH to all persons at risk
of neuropathy (eg, pregnant women;
breastfeeding infants; persons with HIV;
patients with diabetes, alcoholism,
malnutrition, or chronic renal failure; or
patients with advanced age). For patients
with peripheral neuropathy, experts
recommend increasing pyridoxine dose to
100 mg/d.
Adults
5 mg/kg (typically
300 mg)
Children
10–15 mg/kg
. . .
20–30 mg/kg
Rifampin
Capsule (150 mg, 300 mg). Powder may be
suspended for oral administration.
Aqueous solution for intravenous injection.
Adultsc
10 mg/kg (typically
600 mg)
. . .
10 mg/kg (typically
600 mg)
Children
10–20 mg/kg
. . .
10–20 mg/kg
Rifabutin
Capsule (150 mg)
Adultsd
5 mg/kg (typically
300 mg)
. . .
Not recommended
Children
Appropriate dosing for children is unknown. Estimated at 5 mg/kg.
Rifapentine
Tablet (150 mg film coated)
Adults
Ethambutol
Tablet (500 mg scored)
Tablet (100 mg; 400 mg)
10–20 mg/kge
. . .b
10 mg/kg (typically
600 mg)
. . .b
Not recommended
. . .
. . .
Children
Active tuberculosis: for children ≥12 y of age, same dosing as for adults,
administered once weekly. Rifapentine is not FDA-approved for treatment of active
tuberculosis in children <12 y of age.
Adults
See Table 10
. . .
See Table 10
Children
35 (30–40) mg/kg
. . .
50 mg/kg
Adults
See Table 11
. . .
See Table 11
Childrenf
20 (15–25) mg/kg
. . .
50 mg/kg
Adultsg
10–15 mg/kg total
(usually 250–500
mg once or twice
daily)
Children
15–20 mg/kg total
(divided 1–2 times
daily)
Adultsh
15–20 mg/kg total
(usually 250–500
mg once or twice
daily)
Children
15–20 mg/kg total
(divided 1–2 times
daily)
Adults
15 mg/kg daily. Some clinicians prefer 25 mg/kg 3 times weekly.
Patients with decreased renal function may require the 15 mg/kg dose to be given
only 3 times weekly to allow for drug clearance.
Children
15–20 mg/kg [427]
Adults
15 mg/kg daily. Some clinicians prefer 25 mg/kg 3 times weekly.
Patients with decreased renal function, including older patients, may require the 15
mg/kg dose to be given only 3 times weekly to allow for drug clearance.
Children
15–20 mg/kg [427]
Adults
15 mg/kg daily. Some clinicians prefer 25 mg/kg 3 times weekly.
Patients with decreased renal function, including older patients, may require the 15
mg/kg dose to be given only 3 times weekly to allow for drug clearance.
See Table 10
. . .b
See Table 11
. . .b
Second-line drugs
Cycloserine
Ethionamide
Capsule (250 mg)
Tablet (250 mg)
Streptomycin
Aqueous solution (1 g vials) for IM or IV
administration.
Amikacin/
kanamycin
Aqueous solution (500 mg and 1 g vials) for
IM or IV administration.
Capreomycin
Aqueous solution (1 g vials) for IM or IV
administration.
Children
15–20 mg/kg [427]
Para-amino
salicylic acid
Granules (4 g packets) can be mixed in and
ingested with soft food (granules should
not be chewed). Tablets (500 mg) are still
available in some countries, but not in the
United States. A solution for IV
administration is available in Europe.
Adults
8–12 g total (usually
4000 mg 2–3
times daily)
Children
200–300 mg/kg total
(usually divided
100 mg/kg given 2
to 3 times daily)
Tablets (250 mg, 500 mg, 750 mg); aqueous
solution (500 mg vials) for IV injection.
Adults
500–1000 mg daily
Levofloxacin
Children
There are inadequate data to support intermittent
administration.
There are inadequate data to support intermittent
administration.
. . .
. . .
. . .
25–30 mg/kgi
25–30 mg/kgi
25–30 mg/kgi
. . .
. . .
. . .
There are inadequate data to support intermittent
administration.
There are inadequate data to support intermittent
administration.
The optimal dose is not known, but clinical data suggest 15–20 mg/kg [427]
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Pyrazinamide
15 mg/kg
(typically
900 mg)
Table 3
continued.
Drug
Preparation
Moxifloxacin
Population
Tablets (400 mg); aqueous solution (400 mg/
250 mL) for IV injection
Daily
Once-Weekly
Twice-Weekly
Thrice-Weekly
Adults
400 mg daily
There are inadequate data to support intermittent
administration.j
Children
The optimal dose is not known. Some experts use 10 mg/kg daily dosing, though
lack of formulations makes such titration challenging. Aiming for serum
concentrations of 3–5 µL/mL 2 h postdose is proposed by experts as a reasonable
target.
Abbreviations: FDA, US Food and Drug Administration; HIV, human immunodeficiency virus; IM, intramuscular; INH, isoniazid; IV, intravenous.
a
Dosing based on actual weight is acceptable in patients who are not obese. For obese patients (>20% above ideal body weight [IBW]), dosing based on IBW may be preferred for initial doses.
Some clinicians prefer a modified IBW (IBW + [0.40 × (actual weight – IBW)]) as is done for initial aminoglycoside doses. Because tuberculosis drug dosing for obese patients has not been
established, therapeutic drug monitoring may be considered for such patients.
b
For purposes of this document, adult dosing begins at age 15 years or at a weight of >40 kg in younger children. The optimal doses for thrice-weekly therapy in children and adolescents have
not been established. Some experts use in adolescents the same doses as recommended for adults, and for younger children the same doses as recommended for twice-weekly therapy.
c
Higher doses of rifampin, currently as high as 35 mg/kg, are being studied in clinical trials.
d
Rifabutin dose may need to be adjusted when there is concomitant use of protease inhibitors or nonnucleoside reverse transcriptase inhibitors.
e
TBTC Study 22 used rifapentine (RPT) dosage of 10 mg/kg in the continuation phase of treatment for active disease [9]. However, RIFAQUIN and PREVENT TB safely used higher dosages of
RPT, administered once weekly [164, 210]. Daily doses of 1200 mg RPT are being studied in clinical trials for active tuberculosis disease.
g
Clinicians experienced with using cycloserine suggest starting with 250 mg once daily and gradually increasing as tolerated. Serum concentrations often are useful in determining the
appropriate dose for a given patient. Few patients tolerate 500 mg twice daily.
h
Ethionamide can be given at bedtime or with a main meal in an attempt to reduce nausea. Clinicians experienced with using ethionamide suggest starting with 250 mg once daily and gradually
increasing as tolerated. Serum concentrations may be useful in determining the appropriate dose for a given patient. Few patients tolerate 500 mg twice daily.
i
Modified from adult intermittent dose of 25 mg/kg, and accounting for larger total body water content and faster clearance of injectable drugs in most children. Dosing can be guided by serum
concentrations.
j
RIFAQUIN trial studied a 6-month regimen. Daily isoniazid was replaced by daily moxifloxacin 400 mg for the first 2 months, followed by once-weekly doses of moxifloxacin 400 mg and RPT
1200 mg for the remaining 4 months. Two hundred twelve patients were studied (each dose of RPT was preceded by a meal of 2 hard-boiled eggs and bread). This regimen was shown to be
noninferior to a standard daily administered 6-month regimen [164].
may be considered as meeting the definition of “daily” dosing.
There are alternative regimens that are variations of the preferred regimen, which may be acceptable in certain clinical
and/or public health situations (see “Other Regimens” and
“Treatment in Special Situations” in the full-text version of
the guideline).
PICO Question 3: Does intermittent dosing in the intensive phase
have similar outcomes compared to daily dosing in the intensive
phase for treatment of drug-susceptible pulmonary tuberculosis?
Recommendation 3a: We recommend the use of daily rather than
intermittent dosing in the intensive phase of therapy for drugsusceptible pulmonary tuberculosis (strong recommendation;
moderate certainty in the evidence).
Table 4.
Recommendation 3b: Use of thrice-weekly therapy in the intensive
phase (with or without an initial 2 weeks of daily therapy) may be
considered in patients who are not HIV infected and are also at low
risk of relapse (pulmonary tuberculosis caused by drug-susceptible
organisms, that at the start of treatment is noncavitary and/or smear
negative) (conditional recommendation; low certainty in the
evidence).
Recommendation 3c: In situations where daily or thrice-weekly DOT
therapy is difficult to achieve, use of twice-weekly therapy after an
initial 2 weeks of daily therapy may be considered for patients who
are not HIV-infected and are also at low risk of relapse (pulmonary
tuberculosis caused by drug-susceptible organisms, that at the start
of treatment is noncavitary and/or smear negative) (conditional
recommendation; very low certainty in the evidence). Note: If doses
are missed in a regimen using twice-weekly dosing, then therapy is
equivalent to once weekly, which is inferior (see PICO Question 4).
Possible Components of a Multifaceted, Patient-Centered Treatment Strategy
Enablers
Interventions to assist the patient in completing therapy [130]
Incentives
Interventions to motivate the patient, tailored to individual patient
wishes and needs and, thus, meaningful to the patient [130]
Transportation vouchers [30]
Food stamps or snacks and meals [30]
Convenient clinic hours and locations [30]
Restaurant and grocery store coupons [30]
Clinic personnel who speak the languages of the populations served [428]
Assistance in finding or provision of housing [429]
Reminder systems and follow-up of missed appointments [28]
Clothing or other personal products [30]
Social service assistance (referrals for substance abuse treatment and counseling,
housing, and other services) [429]
Books [428]
Outreach workers (bilingual/bicultural as needed; can provide many services related
to maintaining patient adherence, including provision of directly observed therapy,
follow-up on missed appointments, monthly monitoring, transportation, sputum
collection, social service assistance, and educational reinforcement) [428]
Stipends [30]
Integration of care for tuberculosis with care for other conditions [428]
Patient contract [30]
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f
As an approach to avoiding ethambutol (EMB) ocular toxicity, some clinicians use a 3-drug regimen (INH, rifampin, and pyrazinamide) in the initial 2 months of treatment for children who are
HIV-uninfected, have no prior tuberculosis treatment history, are living in an area of low prevalence of drug-resistant tuberculosis, and have no exposure to an individual from an area of high
prevalence of drug-resistant tuberculosis. However, because the prevalence of and risk for drug-resistant tuberculosis can be difficult to ascertain, the American Academy of Pediatrics and most
experts include EMB as part of the intensive-phase regimen for children with tuberculosis.
Table 5.
Therapy
Examples of Priority Situations for the Use of Directly Observed
Patients With the Following Conditions/Circumstances [17, 130, 137, 139,
430, 431]:
• Positive sputum smears
• Delayed culture conversion (sputum obtained at/after
completion of intensive-phase therapy is culture-positive)
• Treatment failure
• Relapse
• Drug resistance
• Homelessness
• Current or prior substance abuse
• Use of intermittent dosing
• HIV infection
• Previous nonadherence to therapy
• Children and adolescents
• Mental, emotional or physical disability (ie, cognitive deficits such as
dementia; neurological deficits; medically fragile patients; or patients with
blindness or severe loss of vision)
• Resident at correctional or long-term care facility
Abbreviation: HIV, human immunodeficiency virus.
Recommended baseline and follow-up evaluations for
patients suspected of having tuberculosis and treated with
first-line medications are summarized in Figure 2. During treatment, a sputum specimen for AFB smear and culture are obtained at monthly intervals until 2 consecutive specimens are
negative on culture. Duration of the continuation phase regimen hinges on the microbiological status at the end of the intensive phase of treatment; thus, obtaining sputum specimens
at the time of completion of 2 months of treatment is critical if
sputum culture conversion to negative has not already been
documented. The culture result of a sputum specimen obtained at the completion of the intensive phase of treatment
(2 months) has been shown to correlate with the likelihood
of relapse after completion of treatment for pulmonary tuberculosis, albeit with low sensitivity [9, 44–46]. Cavitation on the
initial chest radiograph has also been shown to be a risk factor
for relapse [9, 47]. In patients treated for 6 months, having
both cavitation and a positive culture at completion of 2
months of therapy has been associated with rates of relapse
of approximately 20% compared with 2% among patients
with neither factor [9, 45].
In view of this evidence, for patients who have cavitation on
the initial chest radiograph and who have positive cultures at
completion of 2 months of therapy, expert opinion is to extend
the continuation phase with INH and RIF for an additional 3
months (ie, a continuation phase of 7 months in duration, corresponding to a total of 9 months of therapy). Additional factors
to be considered in deciding to prolong treatment in patients
with either cavitation or a positive culture at 2 months (but
not both) might include being >10% below ideal body weight;
being an active smoker; having diabetes, HIV infection, or any
other immunosuppressing condition; or having extensive disease on chest radiograph [46, 48–52].
Interruptions in therapy are common in the treatment of tuberculosis. When interruptions occur, the person responsible for
supervision must decide whether to restart a complete course of
treatment or simply to continue as intended originally. In general, the earlier the break in therapy and the longer its duration,
the more serious the effect and the greater the need to restart
treatment from the beginning (Table 6). Continuous treatment
is more important in the intensive phase of therapy when the bacillary population is highest and the chance of developing drug
resistance greatest. During the continuation phase, the number
of bacilli is much smaller and the goal of therapy is to kill the
persisting organisms. The duration of the interruption and the
bacteriologic status of the patient prior to and after the
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• Previous treatment for active or latent tuberculosis
Figure 2. Baseline and follow-up evaluations for patients treated with first-line
tuberculosis medications. Shading around boxes indicates activities that are optional
or contingent on other information. 1Obtain sputa for smear and culture at baseline,
then monthly until 2 consecutive specimens are negative. Collecting sputa more
often early in treatment for assessment of treatment response and at end of treatment is optional. At least one baseline specimen should be tested using a rapid
molecular test. 2Drug susceptibility for isoniazid, rifampin, ethambutol (EMB), and
pyrazinamide should be obtained. Repeat drug susceptibility testing if patient remains culture positive after completing 3 months of treatment. Molecular resistance
testing should be performed for patients with risk for drug resistance. 3Obtain chest
radiograph at baseline for all patients, and also at month 2 if baseline cultures are
negative. End-of-treatment chest radiograph is optional. Other imaging for monitoring of extrapulmonary disease. 4Monitor weight monthly to assess response to treatment; adjust medication dose if needed. 5Assess adherence and monitor
improvement in tuberculosis symptoms (eg, cough, fever, fatigue, night sweats) as
well as development of medication adverse effects (eg, jaundice, dark urine, nausea,
vomiting, abdominal pain, fever, rash, anorexia, malaise, neuropathy, arthralgias).
6
Patients on EMB: baseline visual acuity (Snellen test) and color discrimination
tests, followed by monthly inquiry about visual disturbance and monthly color discrimination tests. 7Liver function tests only at baseline unless there were abnormalities at baseline, symptoms consistent with hepatotoxicity develop, or for patients
who chronically consume alcohol, take other potentially hepatotoxic medications, or
have viral hepatitis or history of liver disease, human immunodeficiency virus (HIV)
infection, or prior drug-induced liver injury. 8Baseline for all patients. Further monitoring if there are baseline abnormalities or as clinically indicated. 9HIV testing in all
patients. CD4 lymphocyte count and HIV RNA load if positive. 10Patients with hepatitis B or C risk factor (eg, injection drug use, birth in Asia or Africa, or HIV infection)
should have screening tests for these viruses. 11Fasting glucose or hemoglobin A1c
for patients with risk factors for diabetes according to the American Diabetes Association including: age >45 years, body mass index >25 kg/m2, first-degree relative
with diabetes, and race/ethnicity of African American, Asian, Hispanic, American
Indian/Alaska Native, or Hawaiian Native/Pacific Islander. Abbreviations: ALT, alanine aminotransferase; AST, aspartate aminotransferase.
Table 6.
Management of Treatment Interruptionsa
Time Point of
Interruption
Details of Interruption
During intensive
phase
During continuation
phase
Approach
Lapse is <14 d in duration
Continue treatment to complete planned total number of doses (as long as
all doses are completed within 3 mo)
Lapse is ≥14 d in duration
Restart treatment from the beginning
Received ≥80% of doses and sputum was AFB smear
negative on initial testing
Further therapy may not be necessary
Received ≥80% of doses and sputum was AFB smear
positive on initial testing
Continue therapy until all doses are completed
Received <80% of doses and accumulative lapse is <3
mo in duration
Continue therapy until all doses are completed (full course), unless
consecutive lapse is >2 mo
If treatment cannot be completed within recommended time frame for
regimen, restart therapy from the beginning (ie, restart intensive phase,
to be followed by continuation phase)b
Received <80% of doses and lapse is ≥3 mo in
duration
Restart therapy from the beginning, new intensive and continuation phases
(ie, restart intensive phase, to be followed by continuation phase)
Abbreviation: AFB, acid-fast bacilli.
a
According to expert opinion, patients who are lost to follow-up (on treatment) and brought back to therapy, with interim treatment interruption, should have sputum resent for AFB smear,
culture, and drug susceptibility testing.
interruption are also important considerations (see “Interruptions in Therapy” in the full-text version of the guideline).
PICO Question 4: Does intermittent dosing in the continuation phase
have similar outcomes compared to daily dosing in the continuation
phase in patients with drug-susceptible pulmonary tuberculosis
patients?
Recommendation 4a: We recommend the use of daily or thriceweekly dosing in the continuation phase of therapy for drugsusceptible pulmonary tuberculosis (strong recommendation;
moderate certainty in the evidence).
Recommendation 4b: If intermittent therapy is to be administered in
the continuation phase, then we suggest use of thrice-weekly instead
of twice-weekly therapy (conditional recommendation; low certainty
in the evidence). This recommendation allows for the possibility of
some doses being missed; with twice-weekly therapy, if doses are
missed then therapy is equivalent to once weekly, which is inferior.
Recommendation 4c: We recommend against use of once-weekly
therapy with INH 900 mg and rifapentine 600 mg in the continuation
phase (strong recommendation; high certainty in the evidence). In
uncommon situations where more than once-weekly DOT is difficult
to achieve, once-weekly continuation phase therapy with INH 900 mg
plus rifapentine 600 mg may be considered for use only in HIVuninfected persons without cavitation on chest radiography.
PRACTICAL ASPECTS OF TREATMENT
Guidance on the practical aspects of tuberculosis treatment,
drug–drug interactions, therapeutic drug monitoring (TDM),
and management of adverse effects are available in the full-text
version of this guideline. In brief, mild adverse effects usually
can be managed with treatment directed at controlling the symptoms; severe effects usually require the offending drug(s) to be
discontinued, and may require expert consultation on management. If a drug is permanently discontinued, then a replacement
drug, typically from a different drug class, is included in the regimen. Patients with severe tuberculosis often require the initiation
of an alternate regimen during the time the offending drug(s) are
held. In general, for complicated diagnostic or management
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situations, consultation with local and state health departments
is advised. In the United States, the Centers for Disease Control
and Prevention’s Division of Tuberculosis Elimination funds tuberculosis regional training and medical consultation centers
(http://www.cdc.gov/tb/education/rtmc/), which provide medical
consultation to programs and health providers on management
of tuberculosis. In Europe, the World Health Organization
(WHO)/ERS Tuberculosis Consilium (https://www.tbconsilium.
org) provides similar consultation services regarding the diagnosis and treatment of tuberculosis.
Gastrointestinal reactions are common, especially early in
therapy [53]. The optimum approach to management of epigastric distress or nausea with tuberculosis drugs is not clear. To
minimize symptoms, patients receiving SAT may take the medications at bedtime. Gastrointestinal intolerance not associated
with hepatotoxicity can be treated with antacids, which have
less impact on absorption or peak concentration of first-line
drugs than administration with food [54]. Any combination
of otherwise unexplained nausea, vomiting, and abdominal
pain is evaluated with a physical examination and liver function
tests, including alanine aminotransferase (ALT), aspartate aminotransferase (AST), bilirubin, and alkaline phosphatase to assess for possible hepatotoxicity [55]. Drug-induced hepatitis is
the most frequent serious adverse reaction to the first-line
drugs. INH, RIF, and PZA can cause drug-induced liver injury
(DILI), which is suspected when the ALT level is ≥3 times the
upper limit of normal in the presence of hepatitis symptoms, or
≥5 the upper limit of normal in the absence of symptoms. In
either situation, hepatotoxic drugs are stopped immediately
and the patient is evaluated carefully. Other causes of abnormal
liver function tests must be excluded before diagnosing druginduced hepatotoxicity (Table 7). An official American Thoracic
Society statement on the hepatotoxicity of antituberculosis
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b
The recommended time frame for regimen, in tuberculosis control programs in the United States and in several European countries, is to administer all of the specified number of doses for the
intensive phase within 3 months and those for the 4-month continuation phase within 6 months, so that the 6-month regimen is completed within 9 months.
Table 7. Other Causes of Abnormal Liver Function Tests That Should Be
Excluded
Viral hepatitis (hepatitis A, B, and C in all patients; Epstein-Barr virus,
cytomegalovirus, and herpes simplex in immunosuppressed patients)
Biliary tract disease
Alcohol
Other hepatotoxic drugs (eg, acetaminophen, acetaminophen-containing
multiagent preparations, lipid-lowering agents, other drugs)
Select herbal and dietary supplements
Source: American Thoracic Society [56].
TREATMENT IN SPECIAL SITUATIONS
Detailed recommendations on the management of tuberculosis in
special situations (HIV infection, extrapulmonary tuberculosis,
culture-negative pulmonary tuberculosis, advanced age, children,
tuberculosis during pregnancy and breastfeeding, renal disease,
and hepatic disease, among others) are available in the full-text
version of this guideline. Five PICO questions with summary recommendations pertinent to the management of tuberculosis in
HIV patients, steroid use in pericardial or meningeal tuberculosis,
and culture-negative tuberculosis are summarized below.
HIV Infection
Treatment of tuberculosis in patients with HIV infection has
several important differences compared with treatment of patients who do not have HIV infection. The need for antiretroviral therapy (ART), the potential for drug–drug interactions,
especially between the rifamycins and antiretroviral agents
(Table 8), paradoxical reactions that may be interpreted as clinical worsening, and the potential for developing resistance to rifamycins when using intermittent tuberculosis therapy are
some of these differences. Detailed information on these topics
is provided in the full-text version of this practice guideline. In
regard to duration of treatment for drug-susceptible pulmonary
tuberculosis in the presence of HIV infection, our updated systematic review of randomized trials and cohort studies comparing various durations of tuberculosis therapy (6 months vs 8
months or longer), most of which were conducted prior to
the era of highly active ART, showed that the risk of recurrence
is lower when the continuation phase of treatment is extended.
However, it is important to note that the majority of these studies were reports on nonrandomized cohorts, most were completed prior to the era of routine antiretroviral use, many
tested intermittent regimens and few distinguished between reinfection and relapse (see “HIV Infection” in the full-text
PICO Question 5: Does extending treatment beyond 6 months improve
outcomes compared to the standard 6-month treatment regimen
among pulmonary tuberculosis patients coinfected with HIV?
Recommendation 5a: For HIV-infected patients receiving ART, we
suggest using the standard 6-month daily regimen consisting of an
intensive phase of 2 months of INH, RIF, PZA, and EMB followed by a
continuation phase of 4 months of INH and RIF for the treatment of
drug-susceptible pulmonary tuberculosis (conditional
recommendation; very low certainty in the evidence).
Recommendation 5b: In uncommon situations in which HIV-infected
patients do NOT receive ART during tuberculosis treatment, we
suggest extending the continuation phase with INH and RIF for an
additional 3 months (ie, a continuation phase of 7 months in duration,
corresponding to a total of 9 months of therapy) for treatment of drugsusceptible pulmonary tuberculosis (conditional recommendation; very
low certainty in the evidence).
Use of intermittent tuberculosis treatment regimens in HIVinfected patients has been associated with high rates of relapse
and the emergence of drug resistance [9, 59]. In a trial of rifabutin (RFB)–based antituberculosis therapy in combination with
antiretroviral drugs, patients treated with twice-weekly RFB
had a relapse rate of 5.3%, but 8 of 9 patients with relapse
had acquired rifamycin resistance [60]. Relapse and resistance
were associated with low CD4 lymphocyte counts, as all recurrences occurred in patients with baseline CD4 lymphocyte
counts <100 cells/µL. In the pharmacokinetic substudy of the
trial, lower plasma concentrations of RFB and INH were identified as key risk factors for acquiring rifamycin resistance [61].
More recently, the use of a thrice-weekly RIF-based regimen
during the intensive and continuation phases of treatment
was associated with a higher rate of relapse and emergence of
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therapy (http://www.thoracic.org/statements/resources/mtpi/
hepatotoxicity-of-antituberculosis-therapy.pdf ) provides additional details on the management of tuberculosis in the setting of drug-induced liver injury, as well as suggestions on
drug rechallenge [56]; however, the optimal approach to reintroducing tuberculosis treatment after hepatotoxicity is still
not known [57, 58].
version of the guideline). As discussed below, based on data
that show significant reductions in mortality and AIDS-defining
illnesses, patients with HIV infection and tuberculosis should
receive ART in conjunction with daily antituberculosis medications. For HIV-infected patients receiving ART, we suggest
using the standard 6-month daily regimen consisting of an intensive phase of 2 months of INH, RIF, PZA, and EMB followed
by a continuation phase of 4 months of INH and RIF for the
treatment of drug-susceptible pulmonary tuberculosis. In the
uncommon situation in which an HIV-infected patient does
not receive ART during tuberculosis treatment, we suggest extending the continuation phase with INH and RIF for an additional 3 months (ie, a continuation phase of 7 months in
duration, corresponding to a total of 9 months of therapy) for
treatment of drug-susceptible pulmonary tuberculosis (see
PICO Question 5 and Supplementary Appendix B, Evidence
Profile 12). As is noted for drug-susceptible pulmonary tuberculosis in patients without HIV coinfection, the continuation
phase is extended in specific situations that are known to increase risk for relapse, as well as for selected extrapulmonary
sites of disease, namely tuberculous meningitis, and bone,
joint, and spinal tuberculosis (see “Identification and Management of Patients at Increased Risk of Relapse” and “Extrapulmonary Tuberculosis” in the full-text version of the guideline).
Table 8.
Clinically Significant Drug–Drug Interactions Involving the Rifamycinsa
Drugs Whose Concentrations Are Substantially
Decreased by Rifamycins
Drug Class
Antiretroviral agents
RFB preferred with protease inhibitors. For ritonavir-boosted regimens, give
RFB 150 mg daily. Double-dose lopinavir/ritonavir can be used with RIF
but toxicity increased. Do not use RIF with other protease inhibitors.
NNRTIs
Nevirapine
Efavirenz
Rilpivirine
Complera (fixed-dose combination tablet containing
emtricitabine, rilpivirine, TDF)
Etravirine
RIF decreases exposure to all NNRTIs. If nevirapine is used with RIF, lead-in
nevirapine dose of 200 mg daily should be omitted and 400 mg daily
nevirapine dosage given. With RIF, many experts advise that efavirenz be
given at standard dosage of 600 mg daily, although FDA recommends
increasing efavirenz to 800 mg daily in persons >60 kg. In young children
double-dose lopinavir/ritonavir given with RIF results in inadequate
concentrations – super-boosted Lopinavir/ritonavir is advised (if available)
by some experts. Rilpivirine and etravirine should not be given with RIF.
RFB can be used with nevirapine and etravirine at usual dosing. Efavirenz
and RFB use requires dose increase of RFB to 600 mg daily, as such RIF is
preferred. Rilpivirine should not be given with RFB.
INSTIs
Raltegravir
Dolutegravir
Elvitegravir (coformulated with cobicistat, tenofovir and
emtricitabine as Stribild)
Genvoya (fixed-dose combination tablet containing
elvitegravir, cobicistat, emtricitabine, and tenofovir
alafenamide)
Increase dose of raltegravir to 800 mg twice daily with RIF, although clinical
trial data show similar efficacy using 400 mg twice daily. Dolutegravir
dose should be increased to 50 mg every 12 h with RIF. Do not use RIF
with elvitegravir. RFB can be used with all INSTIs.
CCR5 inhibitors
Maraviroc
RIF should not be used with maraviroc. RFB can be used with maraviroc.
Macrolide antibiotics (azithromycin, clarithromycin,
erythromycin)
Azithromycin has no significant interaction with rifamycins. Coadministration
of clarithromycin and RFB results in significant bidirectional interactions
that can increase RFB to toxic levels increasing the risk of uveitis.
Erythromycin is a CYP3A4 substrate and clearance may increase in setting
of rifamycin use.
Doxycycline
May require use of a drug other than doxycycline.
Azole antifungal agents (ketoconazole, itraconazole,
voriconazole, fluconazole, posaconazole,
isavuconazole)
Itraconazole, ketoconazole, and voriconazole concentrations may be
subtherapeutic with any of the rifamycins. Fluconazole can be used with
rifamycins, but the dose of fluconazole may have to be increased.
Atovaquone
Consider alternate form of Pneumocystis jirovecii treatment or prophylaxis.
Chloramphenicol
Consider an alternative antibiotic.
Mefloquine
Consider alternate form of malaria prophylaxis.
Ethinylestradiol, norethindrone
Women of reproductive potential on oral contraceptives should be advised to
add a barrier method of contraception when on a rifamycin.
Tamoxifen
May require alternate therapy or use of a non-rifamycin-containing regimen.
Levothyroxine
Monitoring of serum TSH recommended; may require increased dose of
levothyroxine.
Narcotics
Methadone
RIF and RPT use may require methadone dose increase.
RFB infrequently causes methadone withdrawal.
Anticoagulants
Warfarin
Monitor prothrombin time; may require 2- to 3-fold warfarin dose increase.
Immunosuppressive
agents
Cyclosporine, tacrolimus
RFB may allow concomitant use of cyclosporine and a rifamycin; monitoring
of cyclosporine and tacrolimus serum concentrations may assist with
dosing.
Corticosteroids
Monitor clinically; may require 2- to 3-fold increase in corticosteroid dose.
Anticonvulsants
Phenytoin, lamotrigine
TDM recommended; may require anticonvulsant dose increase.
Cardiovascular
agents
Verapamil, nifedipine, diltiazem (a similar interaction is
also predicted for felodipine and nisoldipine)
Clinical monitoring recommended; may require change to an alternate
cardiovascular agent.
Propranolol, metoprolol
Clinical monitoring recommended; may require dose increase or change to
an alternate cardiovascular drug.
Enalapril, losartan
Monitor clinically; may require a dose increase or use of an alternate
cardiovascular drug.
Digoxin (among patients with renal insufficiency),
digitoxin
TDM recommended; may require digoxin or digitoxin dose increase.
Hormone therapy
Quinidine
TDM recommended; may require quinidine dose increase.
Mexiletine, tocainide, propafenone
Clinical monitoring recommended; may require change to an alternate
cardiovascular drug.
Theophylline
Theophylline
TDM recommended; may require theophylline dose increase.
Sulfonylurea
hypoglycemics
Tolbutamide, chlorpropamide, glyburide, glimepiride,
repaglinide
Monitor blood glucose; may require dose increase or change to an alternate
hypoglycemic drug.
Hypolipidemics
Simvastatin, fluvastatin
Monitor hypolipidemic effect; may require use of an alternate
antihyperlipidemic drug.
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Anti-infectives
Comments
HIV-1 protease inhibitors (lopinavir/ritonavir, darunavir/
ritonavir, atazanavir, atazanavir/ritonavir)
Table 8
continued.
Drug Class
Psychotropic drugs
Drugs Whose Concentrations Are Substantially
Decreased by Rifamycins
Comments
Nortriptyline
TDM recommended; may require dose increase or change to alternate
psychotropic drug.
Haloperidol, quetiapine
Monitor clinically; may require a dose increase or use of an alternate
psychotropic drug.
Benzodiazepines (eg, diazepam, triazolam), zolpidem,
buspirone)
Monitor clinically; may require a dose increase or use of an alternate
psychotropic drug.
Abbreviations: CCR5, C chemokine receptor type 5; CYP, cytochrome P450; FDA, US Food and Drug Administration; HIV, human immunodeficiency virus; INSTI, integrase strand transfer
inhibitor; NNRTI, nonnucleoside reverse transcriptase inhibitor; RFB, rifabutin; RIF, rifampin; RPT, rifapentine; TDF, tenofovir disoproxil fumarate; TDM, therapeutic drug monitoring; TSH,
thyroid-stimulating hormone.
a
See the following useful websites for updated information regarding drug interactions: AIDSinfo, Centers for Disease Control and Prevention, University of California San Francisco, University
of Liverpool, Indiana University, and University of Maryland.
PICO Question 6: Does initiation of ART during tuberculosis
treatment compared to at the end of tuberculosis treatment improve
outcomes among tuberculosis patients coinfected with HIV?
Recommendation 6: We recommend initiating ART during
tuberculosis treatment. ART should ideally be initiated within the first
2 weeks of tuberculosis treatment for patients with CD4 counts <50
cells/µL and by 8–12 weeks of tuberculosis treatment initiation for
patients with CD4 counts ≥50 cells/µL (strong recommendation; high
certainty in the evidence). Note: an exception is patients with HIV
infection and tuberculous meningitis (see Immune Reconstitution
Inflammatory Syndrome).
Patients with HIV infection and tuberculosis are at increased
risk of developing paradoxical worsening of symptoms, signs,
or clinical manifestations of tuberculosis after beginning antituberculosis and antiretroviral treatments. These reactions presumably develop as a consequence of reconstitution of immune
responsiveness brought about by ART, and are designated as the
immune reconstitution inflammatory syndrome (IRIS). Tuberculosis IRIS has been noted to be more common in participants
with earlier ART initiation and CD4+ cell counts <50 cells/µL
[68]. Signs of IRIS may include high fevers, worsening respiratory symptoms, increase in size and inflammation of involved
lymph nodes, new lymphadenopathy, expanding central nervous system lesions, worsening of pulmonary parenchymal infiltrations, new or increasing pleural effusions, and development
of intra-abdominal or retroperitoneal abscesses [69]. Such findings are attributed to IRIS only after excluding other possible
causes, especially tuberculosis treatment failure from drug-resistant tuberculosis or another opportunistic disease, such as nonHodgkin lymphoma or infection.
Management of IRIS is symptomatic. Based on expert opinion, for most patients with mild IRIS, tuberculosis and antiretroviral therapies can be continued with the addition of
anti-inflammatory agents such as ibuprofen. For patients with
worsening pleural effusions or abscesses, drainage may be necessary. For more severe cases of IRIS, treatment with corticosteroids is effective. In a placebo-controlled trial of prednisone for
patients with moderate IRIS, prednisone 1.25 mg/kg/day significantly reduced the need for hospitalization or surgical
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rifamycin resistance in HIV-infected individuals not receiving
antiretrovirals compared with HIV-infected patients also receiving antiretrovirals or HIV-uninfected patients [62]. Based
in part on systematic reviews conducted to obtain evidence in
support of this guideline, our expert opinion is that treatment
of HIV-related tuberculosis be given daily in both the intensive
and continuation phases to avoid recurrent disease and the
emergence of rifamycin resistance (see “Recommended Treatment Regimens” in the full-text version of the guideline).
Mortality among patients with HIV and tuberculosis is high,
principally due to complications of immunosuppression and occurrence of other HIV-related opportunistic diseases. Cotrimoxazole (trimethoprim-sulfamethoxazole) prophylaxis has
been shown to reduce morbidity and mortality in HIV-infected
patients with newly diagnosed tuberculosis [63–65]. Whereas cotrimoxazole is recommended by WHO for all HIV-infected people with active tuberculosis disease regardless of the CD4 cell
count [66], in high-income countries, co-trimoxazole is primarily
used in HIV-infected patients with CD4 counts <200 cells/µL
[67]. The use of ART during tuberculosis treatment in persons
with HIV infection also reduces mortality rates significantly
and decreases the risk of developing AIDS-related conditions.
We performed a systematic review and meta-analysis to address
the concurrent initiation of ART with tuberculosis treatment. On
the basis of high certainty in the evidence that the benefits outweigh the harms, we recommend that patients with tuberculosis
and HIV infection receive ART during antituberculosis treatment. ART should ideally be started within 2 weeks for those patients with a CD4 count <50 cells/µL and by 8–12 weeks for those
with a CD4 count ≥50 cells/µL (see PICO Question 6 and Supplementary Appendix B, Evidence Profile 13). An exception is
HIV-infected patients with tuberculous meningitis, in whom
ART is not initiated in the first 8 weeks of antituberculosis therapy (see full-text version of the guideline). The concurrent administration of antiretrovirals and rifamycins is a major
therapeutic challenge, and additional details on the coadministration of these medications, including the use of RFB, are available in the full-text version of this guideline.
procedures [70]. For patients who develop IRIS, prednisone
may be given at a dose of 1.25 mg/kg/day (50–80 mg/day) for
2–4 weeks, with tapering over a period of 6–12 weeks or longer.
Tuberculous Pericarditis
PICO Question 7: Does the use of adjuvant corticosteroids in
tuberculous pericarditis provide mortality and morbidity benefits?
Recommendation 7: We suggest initial adjunctive corticosteroid
therapy not be routinely used in patients with tuberculous pericarditis
(conditional recommendation; very low certainty in the evidence).
Tuberculous Meningitis
Chemotherapy for tuberculous meningitis is initiated with
INH, RIF, PZA, and EMB in an initial 2-month phase.
After 2 months of 4-drug therapy, for meningitis known or
presumed to be caused by susceptible strains, PZA and
EMB may be discontinued, and INH and RIF continued for
an additional 7–10 months, although the optimal duration
of chemotherapy is not defined. Based on expert opinion, repeated lumbar punctures should be considered to monitor
changes in cerebrospinal fluid cell count, glucose, and protein,
especially early in the course of therapy. In children with tuberculous meningitis, the American Academy of Pediatrics
(AAP) lists an initial 4-drug regimen composed of INH,
RIF, PZA, and ethionamide, if possible, or an aminoglycoside,
followed by 7–10 months of INH and RIF as the preferred regimen [77]. There are no data from controlled trials to guide
the selection of EMB vs an injectable or ethionamide as the
fourth drug for tuberculosis meningitis [78]. Most societies
and experts recommend the use of either an injectable or
EMB. For adults, based on expert opinion, our guideline
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PICO Question 8: Does the use of adjuvant corticosteroids in
tuberculous meningitis provide mortality and morbidity benefits?
Recommendation 8: We recommend initial adjunctive corticosteroid
therapy with dexamethasone or prednisolone tapered over 6–8
weeks for patients with tuberculous meningitis (strong
recommendation; moderate certainty in the evidence).
Culture-Negative Pulmonary Tuberculosis in Adults
Failure to isolate M. tuberculosis from appropriately collected
sputum specimens in persons who, because of clinical or radiographic findings, are suspected of having pulmonary tuberculosis does not exclude a diagnosis of active tuberculosis. Some
causes of failure to isolate organisms include low bacillary populations, inadequate sputum specimens, temporal variations in
the number of expelled bacilli, overgrowth of cultures with other
microorganisms, and errors in specimen processing [92]. Alternative diagnoses must be considered and appropriate diagnostic
studies undertaken in patients who appear to have culturenegative tuberculosis. At a minimum, patients suspected of having pulmonary tuberculosis have 2 sputum specimens (using
sputum induction with hypertonic saline if necessary) for
AFB smears and cultures for mycobacteria or for rapid molecular testing for M. tuberculosis as part of the diagnostic evaluation. Other diagnostic procedures, such as bronchoscopy with
bronchoalveolar lavage and biopsy, are considered before making a presumptive diagnosis of culture-negative tuberculosis.
Patients who, on the basis of careful clinical and radiographic
evaluation, are thought to have pulmonary tuberculosis should
have treatment initiated with INH, RIF, PZA, and EMB even
when the initial sputum smears are negative. If M. tuberculosis
is isolated in culture or a rapid molecular test is positive, treatment for active disease is continued for a full, standard 6-month
course (Table 2), if appropriate based on drug susceptibility test
results. Patients who have negative cultures but who still are presumed to have pulmonary tuberculosis should have thorough
clinical and radiographic follow-up after 2–3 months of therapy
[93]. If there is clinical or radiographic improvement and no
other etiology is identified, treatment should be continued.
The optimum treatment regimens and duration for smearnegative, culture-negative tuberculosis have not been convincingly established. We performed a systematic review that evaluated
treatment regimens of varying durations in adult patients with
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Based on small studies that have shown mortality and morbidity
benefits [71–73], corticosteroids have previously been universally
recommended in combination with a standard 6-month regimen
(Table 2) for treating tuberculosis pericarditis; however, a recent
placebo-controlled randomized clinical trial with 1400 participants did not find a difference in the combined primary endpoint
of the trial, which included mortality, cardiac tamponade, or constrictive pericarditis, between patients treated with adjunctive corticosteroids vs placebo [74]. A subgroup analysis, however, did
suggest a benefit in preventing constrictive pericarditis. Similarly,
a systematic review conducted to obtain evidence in support of
this guideline did not find a statistically significant benefit in
terms of mortality or constrictive pericarditis from the use of corticosteroids [71–75]. Therefore, we suggest that adjunctive corticosteroids should not be used routinely in the treatment of
patients with pericardial tuberculosis (see PICO Question 7 and
Supplementary Appendix B, Evidence Profile 14). However, selective use of corticosteroids in patients who are at the highest
risk for inflammatory complications might be appropriate.
Such patients might include those with large pericardial effusions,
those with high levels of inflammatory cells or markers in pericardial fluid, or those with early signs of constriction [76].
committee prefers using EMB as the fourth drug in the regimen for tuberculous meningitis.
The role of adjunctive corticosteroid therapy in the treatment
of tuberculous meningitis has been reported by numerous studies [79–91], and our updated systematic review found a mortality benefit from the use of adjuvant corticosteroids. Therefore,
we recommend adjunctive corticosteroid therapy with dexamethasone or prednisolone tapered over 6–8 weeks for patients
with tuberculous meningitis (see PICO Question 8 and Supplementary Appendix B, Evidence Profile 15).
culture-negative, paucibacillary tuberculosis, and we suggest
that a 4-month treatment regimen is adequate for smearnegative, culture-negative pulmonary tuberculosis (see PICO
Question 9 and Supplementary Appendix B, Evidence Profile
16). Operationally, treatment is initiated with an intensive
phase of INH, RIF, PZA, and EMB daily and continued even
when the initial bacteriologic studies are negative. If all cultures
on adequate samples are negative (defining culture-negative tuberculosis) and there is clinical or radiographic response after 2
months of intensive phase therapy, the continuation phase with
INH and RIF can be shortened to 2 months. Alternatively, if
there is concern about the adequacy of workup or the accuracy
of the microbiologic evaluations, a standard 6-month regimen remains preferred (see Table 2 and “Culture-Negative Pulmonary
Tuberculosis” in the full-text version of the guideline) [14, 15].
CONCLUSIONS
Treatment of tuberculosis is focused on both curing the individual patient and minimizing the transmission of M. tuberculosis
to other persons, thus, successful treatment of tuberculosis has
benefits both for the individual patient and the community in
which the patient resides. A 4-drug regimen of INH, RIF, PZA,
and EMB remains the preferred initial treatment for drugsusceptible pulmonary tuberculosis. Treatment is initiated
promptly even before AFB smear microscopy, molecular tests,
and mycobacterial culture results are known in patients with
high likelihood of having tuberculosis or those seriously ill
with a disorder suspicious for tuberculosis. Initiation of treatment should not be delayed because of negative AFB smears
for patients in whom tuberculosis is suspected and who have
a life-threatening condition. There are variations of the preferred regimen that are appropriate in certain public health situations or in special clinical situations. Additional detailed and
extensively referenced information on treatment of tuberculosis
in special situations ( patients with renal disease or hepatic disease, those of advanced age, etc), the use of case management
strategies (including DOT), regimen and dosing selection in
adults and children (daily vs intermittent), the role of TDM,
treatment of tuberculosis in the presence of HIV infection (duration of tuberculosis treatment and timing of initiation of
ART), treatment of tuberculosis in children, treatment of tuberculosis during pregnancy, and treatment of extrapulmonary tuberculosis, as well as key research priorities, are provided in the
full-text version of this practice guideline.
The ATS, the CDC, and the IDSA have jointly developed this
guideline for the treatment of drug-susceptible tuberculosis.
This document provides guidance on the clinical and public
health management of tuberculosis in low-incidence countries.
The current document differs from its predecessor, published
in 2003 [94], in 3 important areas. First, the process by which the
recommendations were developed was substantially modified.
For the first time, the Guideline Writing Committee based its recommendations on the certainty in the evidence (also known as
the quality of evidence) assessed according to the GRADE methodology (see Supplementary Appendix A: Methods), which incorporates patient values and costs as well as judgments about
trade-offs between benefits and harms [1, 2]. A carefully selected
panel of experts, screened for conflicts of interest, including specialists in pulmonary medicine, infectious diseases, pharmacokinetics, pediatrics, primary care, public health, and systematic
review methodology were assembled to assess the evidence supporting each recommendation. The GRADE method was used to
assess the certainty in the evidence and to rate the strength of the
recommendations. Second, the ERS has become an endorser of
the statement, along with the US NTCA. Representatives from
the AAP, the Canadian Thoracic Society, the International
Union Against Tuberculosis and Lung Disease, and the WHO
also participated in the development of this guideline. Together,
these committee members served to provide broader input, thereby expanding the applicability of the guidance beyond North
America to include Europe and other low-incidence settings.
Last, practice guidelines for the treatment of drug-resistant tuberculosis (including INH monoresistance) are no longer included in
this statement and are now covered in a separate practice guideline
under development by the ATS, CDC, ERS, and IDSA.
Whereas significant changes have been made, the current
document also retains many of the basic principles of tuberculosis care described in the 2003 version. As before, a fundamental aspect of tuberculosis care, regardless of the treatment
selected, is ensuring patient adherence to the drug regimen
and successful completion of therapy. The responsibility for
successful treatment of tuberculosis is placed primarily on the
provider or program initiating therapy rather than on the patient. It is well established that appropriate treatment of tuberculosis rapidly renders the patient noninfectious, prevents drug
resistance, minimizes the risk of disability or death from tuberculosis, and nearly eliminates the possibility of relapse [95]. Provider responsibility is a central concept in treating patients with
tuberculosis, no matter what the source of their care.
The recommendations in this statement are not applicable
under all epidemiological circumstances or across all levels of
resources that are available to tuberculosis control programs
worldwide. It should be emphasized that these guidelines are intended for areas in which mycobacterial cultures, molecular and
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PICO Question 9: Does a shorter duration of treatment have similar
outcomes compared to the standard 6-month treatment duration
among HIV-uninfected patients with paucibacillary tuberculosis (ie,
smear negative, culture negative)?
Recommendation 9: We suggest that a 4-month treatment regimen is
adequate for treatment of HIV-uninfected adult patients with AFB
smear- and culture-negative pulmonary tuberculosis (conditional
recommendation; very low certainty in the evidence).
BACKGROUND
phenotypic drug susceptibility tests, and radiographic facilities
are available on a routine basis—typically low-incidence (<100
tuberculosis cases per million population), well-resourced
countries, where in some settings tuberculosis epidemiology is
at or nearing preelimination levels (<10 cases per million) [96,
97]. The WHO has developed tuberculosis practice guidelines
(currently under revision) specifically for high-incidence, resource-limited areas of the world [98].
OBJECTIVES OF ANTITUBERCULOSIS THERAPY
Treatment of tuberculosis is focused on both curing the individual patient and minimizing the transmission of Mycobacterium
tuberculosis to other persons; successful treatment of tuberculosis has benefits both for the individual patient and the community in which the patient resides.
The objectives of tuberculosis therapy are:
Sixty-five years of investigation, including many clinical trials, have consistently supported the requirement for treatment
with multiple drugs to achieve these objectives, minimize drug
toxicity, and maximize the likelihood of treatment completion
[3, 4]. The most effective agents to curtail rapid multiplication of
tuberculous bacilli are INH and the fluoroquinolones. Persisting
bacilli appear to curtail their metabolic activity; drugs known to
be effective against such persisters include the rifamycins and
PZA, the latter with activity believed limited to special microenvironments of relatively increased acidity [99].
Objective 1: Rapid killing of multiplying bacilli (“bactericidal effect”): Rapid reduction in the number of replicating bacilli reduces
mortality risk [100, 101], and appears to diminish infectiousness,
but even optimal therapy on average requires 4–5 weeks to render
sputum cultures negative [102–105]. Studies of early bactericidal
activity (EBA) measure the rate of decline in bacillary numbers
in sputum during the initial 1–2 weeks of treatment; EBA studies
have been used in the initial evaluation of virtually every new tuberculosis drug since 1980 [106, 107]. However, the relationship of
a drug or regimen’s EBA to its ability to achieve durable cure is still
uncertain [108]. For example, INH has a remarkable EBA but acts
only slowly on persisting bacilli; RIF at the dose currently used (10
mg/kg) has moderate EBA but potent activity against persisters;
and PZA has almost no measurable EBA, but acts potently to assist
in achieving durable cure [99, 109].
Objective 2: Achievement of relapse-free cure (“sterilizing effect”): Demonstration of relapse-free cure requires lengthy clinical trials. Among the few drugs effective in preventing relapse,
the most prominent have been the rifamycins. Rapid and
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1. To reduce the bacillary population rapidly thereby decreasing severity of the disease, preventing death and halting
transmission of M. tuberculosis;
2. To eradicate persisting bacilli in order to achieve durable
cure ( prevent relapse) after completion of therapy; and
3. To prevent acquisition of drug resistance during therapy.
reliable measurement of the sterilizing effect of antituberculous
agents remains elusive. In vitro models are not entirely predictive [110, 111]. The most commonly used animal model is the
murine model, which has reliably reproduced the results of
standard short-course chemotherapy [112]; however, the murine model has been criticized because mice do not develop cavities and caseous necrosis, pathologic hallmarks of human
tuberculosis [113]. Other animal models have been proposed,
but none fully replicates the human response to M. tuberculosis
[114]. Recent evidence suggests that extracellular bacilli in necrotic material within cavities may be the major challenge to
prevention of relapse after therapy. Studies using sensitive analytic tools such as positron emission tomography–computed tomography scanning and matrix-assisted laser desorption/
ionization mass spectrometry imaging in experimental animals
and in patients undergoing pulmonary resection have provided
evidence of the marked differences in the ability of key drugs
(RIF, PZA, levofloxacin, moxifloxacin) to penetrate into pulmonary tissue, into the cellular granuloma, and into caseous material within cavities [115–119]. However, the pathologic sites
from which relapses arise remain unclear.
Objective 3: Protection against acquisition of drug resistance
(through use of multidrug therapy): The basic biology underlying
the acquisition of drug resistance is well understood, though the
details involving some individual agents are still uncertain. As a
rule, genetic mutations conferring substantial resistance to individual antituberculous agents occur at constant low rates. For example, rifamycins act primarily by inhibiting the action of
bacterial RNA polymerase in the translation of DNA to RNA,
by binding to and obstructing access to a subunit of the bacterial
RNA polymerase. Mutations in a relatively limited (81 base pairs
[bp]) genomic segment encoding for this subunit lead to obstruction of rifamycin binding to the polymerase β subunit (rpoB);
more than half a dozen amino acid substitutions conferring RIF
resistance have been well described. In the case of PZA, resistance
is most often conferred by mutations in the pncA gene, which encodes for an amidase that is required to convert PZA, a prodrug,
into its active form, pyrazinoic acid. The pncA mutations occur
throughout the 350-bp gene, with no notable preference for
specific mutations yet described. INH is also a prodrug requiring activation by a bacterial catalase-peroxidase enzyme (encoded by katG), coupling with NADH, and binding to an
acyl carrier protein reductase (encoded by inhA); the process
inhibits the synthesis of mycolic acid needed for the mycobacterial cell wall. Resistance to INH arises through multiple
mechanisms, including loss of the katG-encoded catalase peroxidase activity, and overexpression or alterations in the inhAencoded reductase [120].
The frequency of mutation engendering resistance to specific
agents was estimated some 40 years ago; the highest proportion
of resistant mutants expected in an unselected bacterial population were 3.5 × 10−6 for INH and 3.1 × 10−8 for RIF [4, 121].
Multiple Factors Influence the Outcome of Tuberculosis Treatment
Multiple interrelated factors have been associated with the outcome of tuberculosis therapy. These include:
• Patient factors, such as age, comorbid conditions, immunologic competence, nutritional status, alcohol abuse;
• Radiographic features, such as extent of disease, presence
and size of cavities;
• Microbiologic factors, such as baseline colony count, culture positivity at 2 or 3 months;
• Genetic factors, including individual genetic features of
drug absorption and metabolism, individual vulnerability to
toxicities, immunologic characteristics;
• Programmatic factors, including adherence support interventions (enhancers, enablers, monitoring, supervision/DOT),
dosing frequency;
• Pharmacokinetic factors, such as absorption, metabolism, protein binding, drug clearance, total drug quantities
administered;
• Bacillary factors, such as drug tolerance, strain susceptibilities to drugs in the regimen; and
• Regimen factors, such as number of active drugs, bactericidal and sterilizing potency, synergy or antagonism, and duration of therapy in relation to drugs employed.
The success of therapy depends upon many diverse elements,
only some of which are presently predictable, identifiable, or
modifiable. Numerous studies have found an increased risk of
relapse among patients with signs of more extensive disease
(ie, cavitation or more extensive disease on chest radiograph)
[5–9], and/or slower response to treatment (ie, culture status
at 2 or 3 months) [4, 6, 10, 11]. Better understanding of the causal pathways through which these elements exert their effect, and
greater ability to identify and quantify each of these, should lead
to increased therapeutic success, and will inform efforts to develop shorter, less toxic, and better-tolerated treatment regimens in the future [122].
ORGANIZATION AND SUPERVISION OF TREATMENT
PICO Question 1: Does adding case management interventions to
curative therapy improve outcomes compared to curative therapy
alone among patients with tuberculosis?
(Case management is defined as patient education/counseling, field/
home visits, integration/coordination of care with specialists and
medical home, patient reminders, incentives/enablers).
Recommendation 1: We suggest using case management
interventions during treatment of patients with tuberculosis
(conditional recommendation; low certainty in the evidence).
PICO Question 2: Does self-administered therapy (SAT) have similar
outcomes compared to directly observed therapy (DOT) in patients
with various forms of tuberculosis?
Recommendation 2: We suggest using DOT rather than SAT for
routine treatment of patients with all forms of tuberculosis
(conditional recommendation; low certainty in the evidence).
Role of Health Department
Due to the public health implications of prompt diagnosis and
effective treatment of tuberculosis, most low-incidence countries designate a government public health agency as having
legal authority for controlling tuberculosis [12, 13]. To effectively carry out this charge, the public health agency conducts ongoing epidemiologic surveillance of tuberculosis, ensures access
to quality-assured microbiological laboratory services, maintains an uninterrupted supply of antituberculosis medications,
and monitors and reports treatment outcomes [13]. The public
health agency may also have the authority to apply legal measures in situations of nonadherence as a last resort where other
interventions have been pursued without effect. In some jurisdictions diagnostic and treatment services are provided directly
by the public health agency, whereas in others, these services are
provided by the private sector or by a combination of public and
private providers.
Patient-Centered Care and Case Management
Patient-centered care respects an individual’s right to participate actively as an informed partner in decisions and activities
related to tuberculosis diagnosis and treatment [123, 124]. The
Institute of Medicine defines patient-centered care as “providing care that is respectful of and responsive to individual patient
preferences, needs, and values, and ensuring that patient values
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Because these mutations generally occur independently, the likelihood of simultaneous resistance mutations to both INH and
RIF is in the range of 11 × 10−14. Thus, in patients with very
high bacillary burdens, the occurrence of mutations conferring
resistance to a single drug is likely, to 2 drugs is possible, but
to 3 drugs is highly unlikely [10]. Acquisition of drug resistance
might occur more readily if there is irregular or sporadic drug
taking, inadequate drug absorption, inadequate drug dosing, or
ill-informed use of single drug treatment (either by error, or because tuberculosis has not been recognized or considered). If resistance to a specific drug occurs, then the resistant clone will
possess an advantage relative to susceptible strains when confronted with that drug, and will have no advantage (or possibly
a modest disadvantage, if the mutation confers some biologic
“cost”) if the drug is not used. In the situation of the standard
3-drug regimen (INH, RIF, PZA), 3 circumstances must likely
be present for resistance to RIF to emerge: (1) some mutant bacilli resistant to RIF must be present or appear; (2) the bacilli
must be exposed to RIF to favor multiplication of the resistant
bacteria; and (3) INH and PZA must not be present in sufficient
concentration to offset the survival advantage enjoyed by the
RIF-resistant clones; this could occur because they are not employed at all (ie, single drug therapy), or because some combination of circumstances affects the other drugs (eg, a nonacidic
compartment is involved thereby disadvantaging PZA, and
INH happens to be rapidly metabolized [so-called rapid acetylation due to genetic polymorphisms affecting N-acetyl transferase], so that INH is not present in adequate concentration) [59].
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Supplementary Appendix B, Evidence Profiles 1–3). For these
reasons, we suggest using case management interventions during treatment of patients with tuberculosis (Recommendation 1:
conditional recommendation; very low certainty in the evidence).
Approaches to Ensuring Adherence and Treatment Success
Given the critical importance of chemotherapy, both to the patient and to the public, approaches to ensuring adherence to the
treatment regimen are a major focus of the overall management
plan. To maximize completion of therapy, management strategies should utilize a broad range of approaches. Among these,
DOT, the practice of observing the patient swallow her or his
antituberculosis medications, has been widely used and deserves special emphasis. To be consistent with the principles
of patient-centered care, decisions regarding the use of DOT
must be made in concert with the patient [14–16]. For example,
DOT can be provided in the office, clinic, or in the “field” ( patient’s home, place of employment, school, or any other site that
is mutually agreeable) by appropriately trained personnel [32].
DOT enables early identification of adverse drug reactions, clinical worsening of tuberculosis, and nonadherence [33]. Moreover, frequent contact with the patient allows providers to
facilitate linkage to other medical care and services.
However, the implementation of DOT may not be readily
feasible when resources are limited [129]. In such circumstances, patients who are more likely to present a transmission risk to
others or are more likely to have difficulty with adherence are
prioritized for DOT [17]. In addition, experts advise that
DOT must be used with regimens that use intermittent drug administration because of the potential serious consequences of
missed doses. Careful attention is needed to ensure that ingestion of the medication is, in fact, observed, as the use of DOT
does not guarantee ingestion of all doses of every medication
[130]. Patients may miss appointments, may not actually swallow the tablets or capsules, or may deliberately regurgitate the
medications. Consequently, the use of DOT does not mitigate
the continued need for monitoring for signs of treatment failure. DOT is also advised for all patients residing in institutional
settings such as hospitals, nursing homes, opiate replacement
clinics, or correctional facilities. In special populations such as
individuals with treatment failure, recurrence, or at risk for
disseminated tuberculosis (eg, HIV coinfected), experts recommend against the use of SAT given the risks involved in developing drug resistance (Table 5). In recent years, DOT has
expanded to other modalities such as web-based video and mobile phones, which have been well received by both patients and
health department staff [131–133]. Special attention to maintaining patient privacy is needed when web-based and wireless
modalities are used for monitoring.
Systematic reviews of studies conducted in countries with
high, medium, and low burdens of tuberculosis have not
shown improvement in cure or treatment completion in
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guide all clinical decisions” [125]. Given that tuberculosis treatment requires multiple drugs be given for several months, it is
crucial that the patient be involved in a meaningful way in making decisions concerning treatment supervision and overall
care. International standards have been developed that also support using patient-centered approaches to the management of
tuberculosis [14–16].
The optimal organization of tuberculosis treatment often requires the coordination not only of primary and specialty clinical
care services, but also community-based organizations and agencies in the public and private sectors [14–16]. The inherent complexities of the healthcare delivery system combined with the
diversity of characteristics of patients are best addressed by providing individualized patient-centered case management [13]. In
most settings, a patient is assigned a case manager who assesses
needs and barriers that may interfere with treatment adherence
[17]. With active input from the patient and healthcare providers,
the case manager, together with the patient, develops an individualized case management plan with interventions to address the
identified needs and barriers [18–20]. The plan is reviewed periodically and revised as needed with the patient and medical team
to evaluate the clinical response to therapy, monitor potential
drug toxicities, and address any challenges identified with adherence. The spectrum of interventions for achieving adherence may
range from routine monthly monitoring to legal confinement
[126, 127], with confinement being used only as a last resort.
The least restrictive public health interventions that are effective
are used to achieve adherence.
Key considerations when developing a case management
plan include (1) improving “treatment literacy” by educating
the patient about tuberculosis and its treatment, including possible adverse effects [21, 22]; (2) discussing expected outcomes
of treatment, specifically the ability to cure the patient of the
disease; (3) reviewing methods of supervision and assessing response to therapy; and (4) discussing infectiousness and infection control measures using terminology that is appropriate to
the culture, language, age, and reading level of the patient [23].
For non-English-speaking patients, the use of medical interpreter services is preferred over using family or friends as interpreters [24]. Relevant information should be reinforced at each
visit. Other components of the patient-centered case management plan include, but are not limited to, setting up patient reminders and systems to follow-up missed appointments [23, 28,
29], use of incentives and enablers [25–27, 30, 31], field and
home visits [32], integration and coordination of tuberculosis
care with the patient’s primary and specialty care, and legal interventions when indicated (Table 4). Overall, the quality of evidence is variable in the few studies examining the impact of
case management interventions on outcomes such as treatment
success; however, these studies suggest that for the most part,
patient-centered case management interventions are helpful
with little evidence of harm to patients [128] (see
Transfers Between Jurisdictions
Patients being treated for tuberculosis who move from one jurisdiction to another before completion of therapy are more
likely to be lost to follow-up than patients who do not move
[141]. In the United States, health departments track patients
via interjurisdictional referrals, and can use other patient tracking mechanisms (eg, TBNet at http://www.migrantclinician.org/
services/network/tbnet.html) for patients who travel internationally) [142–144].
Legal Interventions to Protect Public Health
In extreme circumstances, nonadherent patients may be subject
to legal intervention in the form of court-ordered medical examination, DOT, completion of therapy, or civil or criminal detention for completion of tuberculosis treatment when less
restrictive measures have been tried and shown to fail [126,
127, 145]. These situations involve special circumstances such
as drug resistance, evidence of treatment failure or relapse,
and continued concern for transmission in the community,
thereby justifying the temporary restriction of individual rights
to protect the public’s health and safety. Public health laws exist
in most jurisdictions that allow these legal interventions, at least
for patients who remain infectious, but they should be pursued
as a plan of last resort. In the United States, health departments
have the sole authority to initiate legal action, and generally the
interventions produce good outcomes with treatment completion rates >95% [126, 127]. Outside the United States, legal authority to enforce tuberculosis adherence may originate in other
government agencies outside the health department [146].
RECOMMENDED TREATMENT REGIMENS
PICO Question 3: Does intermittent dosing in the intensive phase
have similar outcomes compared to daily dosing in the intensive
phase for treatment of drug-susceptible pulmonary tuberculosis?
Recommendation 3a: We recommend the use of daily rather than
intermittent dosing in the intensive phase of therapy for drugsusceptible pulmonary tuberculosis (strong recommendation;
moderate certainty in the evidence).
Recommendation 3b: Use of thrice-weekly therapy in the intensive
phase (with or without an initial 2 weeks of daily therapy) may be
considered in patients who are not HIV-infected and are also at low
risk of relapse (pulmonary tuberculosis caused by drug-susceptible
organisms, that at the start of treatment is noncavitary and/or smear
negative) (conditional recommendation; low certainty in the
evidence).
Recommendation 3c: In situations where daily or thrice-weekly DOT
therapy is difficult to achieve, use of twice-weekly therapy after an
initial 2 weeks of daily therapy may be considered for patients who
are not HIV-infected and are also at low risk of relapse (pulmonary
tuberculosis caused by drug-susceptible organisms, that at the start
of treatment is noncavitary and/or smear negative) (conditional
recommendation; very low certainty in the evidence). Note: If doses
are missed in a regimen using twice-weekly dosing then therapy is
equivalent to once weekly, which is inferior (see PICO Question 4).
PICO Question 4: Does intermittent dosing in the continuation phase
have similar outcomes compared to daily dosing in the continuation
phase in patients with drug-susceptible pulmonary tuberculosis
patients?
Recommendation 4a: We recommend the use of daily or thriceweekly dosing in the continuation phase of therapy for drugsusceptible pulmonary tuberculosis (strong recommendation;
moderate certainty in the evidence).
Recommendation 4b: If intermittent therapy is to be administered in
the continuation phase, then we suggest use of thrice-weekly instead
of twice-weekly therapy (conditional recommendation; low certainty
in the evidence). This recommendation allows for the possibility of
some doses being missed; with twice-weekly therapy, if doses are
missed then therapy is equivalent to once weekly, which is inferior.
Recommendation 4c: We recommend against use of once-weekly
therapy with INH 900 mg and rifapentine (RPT) 600 mg in the
continuation phase (strong recommendation; high certainty in the
evidence). In uncommon situations where more than once-weekly
DOT is difficult to achieve, once-weekly continuation phase therapy
with INH 900 mg plus RPT 600 mg may be considered for use only in
HIV-uninfected persons without cavitation on chest radiography.
Deciding to Initiate Treatment
Empiric treatment with a 4-drug regimen is initiated promptly
in patients (children and adults) with high likelihood of having
tuberculosis or those seriously ill with a disorder suspicious for
tuberculosis, even before AFB smear microscopy, molecular
tests, and mycobacterial culture results are known. Initiation
of treatment is not delayed because of negative AFB smears
for patients in whom tuberculosis is suspected and who have
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patients receiving their antituberculosis treatment by DOT
compared with SAT [134–136]. The systematic review conducted to obtain evidence in support of this practice guideline also
did not find any significant differences between SAT and DOT
when assessing several outcomes of interest, including mortality, treatment completion, and relapse (see Supplementary Appendix B, Evidence Profile 4). However, DOT was significantly
associated with improved treatment success (the sum of patients
cured and patients completing treatment) and with increased
sputum smear conversion during treatment, as compared to
SAT. Because DOT is a multifaceted public health intervention
that is not amenable to the conventional clinical trials approaches to assessing benefits, and because participation in
DOT can be advantageous for early recognition of adverse
drug reactions and treatment irregularities, for allowing providers to establish rapport with the patient and for addressing treatment complications expeditiously, DOT remains the standard
of practice in the majority of tuberculosis programs in the United States [33–35] and Europe [15]. Population-based studies
(representing a low quality of evidence) have suggested that tuberculosis treatment by DOT in comparison to SAT is associated with a reduction in the acquisition and transmission of drugresistant M. tuberculosis (Texas), increased treatment success in
HIV-infected patients receiving RFB-containing regimens,
shorter duration for completion of treatment (New York
City), higher treatment completion rates in incarcerated patients transitioning to the community (Chicago), and a reduction in mortality and loss to follow-up (Brazil) [34, 137–140].
Consequently, we suggest using DOT rather than SAT for routine treatment of patients for all forms of tuberculosis (Recommendation 2: conditional recommendation; low certainty in the
evidence).
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clarify the situation (usually within 2 months). An advantage
of the early use of combination chemotherapy is that once active
disease is excluded by negative cultures and lack of clinical or
radiographic response to treatment, the patient will have completed 2 months of combination treatment that can be applied
to the total duration of treatment for latent tuberculosis infection. Even when the suspicion for active tuberculosis is low,
treatment for latent tuberculosis infection with a single drug
is not initiated until active tuberculosis has been excluded, usually by negative cultures.
In general, for complicated diagnostic or management situations, consultation with local and state health departments is
advised. In the United States, the CDC’s Division of Tuberculosis Elimination funds tuberculosis regional training and medical
consultation centers (http://www.cdc.gov/tb/education/rtmc/),
which provide medical consultation to programs and health
providers on management of tuberculosis. In Europe, the
WHO and ERS Tuberculosis Consilium (https://www.
tbconsilium.org) provides similar consultation services regarding the diagnosis and treatment of tuberculosis.
Regimens
The preferred regimen and other choices are listed in Table 2.
Patient factors should be considered when selecting administration schedule (intermittency), and in some instances regimen
composition. Feasibility of DOT is sometimes an additional
consideration when selecting frequency of administration.
Regimens for adults and children are identical except in uncommon circumstances where it may be acceptable to omit EMB
from the initial treatment regimen for young children (see
“Children”). For all regimens, patients are treated until they
have received the specified total number of doses for the treatment regimen (ie, not solely based on duration of treatment).
Preferred Regimen
The preferred regimen for treating adults with tuberculosis
caused by organisms that are not known or suspected to be
drug resistant is a regimen consisting of an intensive phase of
2 months of INH, RIF, PZA, and EMB followed by a continuation phase of 4 months of INH and RIF [3, 36, 37]. To reduce
the risk of relapse, the continuation phase of treatment is extended for an additional 3 months for patients who had cavitation on the initial (or follow-up) chest radiograph and, in
addition, are culture positive at the time of completion of the
intensive phase of treatment.
The intensive phase of treatment consists of 4 drugs (INH,
RIF, PZA, EMB) because of the current proportion of new tuberculosis cases worldwide caused by organisms that are resistant to INH [38–41]; however, if therapy is being initiated after
drug susceptibility test results are known and the patient’s isolate is susceptible to both INH and RIF, EMB is not necessary,
and the intensive phase can consist of INH, RIF, and PZA only.
EMB can be discontinued as soon as the results of drug
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a life-threatening condition. The decision to initiate combination chemotherapy for tuberculosis is based on multiple factors
including clinical, radiographic, laboratory, patient, and public
health factors (Figure 1). Clinical judgment and index of suspicion also play a critical role in deciding to initiate treatment. In
addition to smear microscopy and mycobacterial culture, CDC
recommends the use of a rapid molecular test on at least one
specimen from each patient with signs and symptoms of pulmonary tuberculosis for whom a diagnosis of tuberculosis is
being considered but has not been established, and for whom
the test result would alter case management or tuberculosis control activities [147]. Use of molecular tests directly on clinical
samples has been shown to shorten time to diagnosis, and
some tests have the additional ability to provide information
on drug susceptibility [147, 148].
In the presence of a clinical syndrome compatible with tuberculosis, a positive AFB smear provides strong inferential evidence for the diagnosis of tuberculosis. If the diagnosis is
confirmed by isolation of M. tuberculosis or a positive rapid molecular test, or is strongly inferred from clinical or radiographic
improvement consistent with a response to tuberculosis treatment, the regimen is continued to complete a standard course
of therapy. In patients with a positive AFB smear, but a negative
rapid molecular test (including an assessment for polymerase
chain reaction inhibitors, reported to be present in 2%–5% of
respiratory specimens tested by nucleic acid amplification
tests [149, 150]), it is unlikely that the positive smear is due to
M. tuberculosis, particularly when molecular testing of a second
smear-positive specimen is also negative [147]. If empiric treatment is started, cultures throughout are negative, and there is no
response to treatment, yet the interferon-γ release assay (IGRA)
or purified protein derivative (PPD)–tuberculin skin test (TST)
is positive, consideration is given to treatment of latent tuberculosis infection using the following options: (1) stop treatment if
RIF and PZA were included in the initial empiric 4-drug therapy, administered for at least 2 months [151]; (2) continue treatment with RIF, with or without INH, for a total of 4 months; (3)
give 12 weekly doses of INH/RPT by DOT [152]; or (4) continue treatment with INH for a total of 9 months [83, 153, 154]. In
patients in whom there is a low suspicion for active tuberculosis
(not initially treated), if cultures remain negative, the IGRA or
PPD-TST is positive (≥5 mm), and the abnormal chest radiograph is unchanged after 2 months (ATS/CDC class 4), treatment for latent tuberculosis infection is indicated [155]. If not
previously treated, these patients are at increased risk for development of active tuberculosis with case rates 2.5–19 times higher than those of persons infected by M. tuberculosis with normal
chest radiographs [156–159]. These patients are high-priority
candidates for treatment of latent tuberculosis infection.
If clinical suspicion for active tuberculosis is low, the options
are to begin treatment with combination chemotherapy or to
defer treatment until additional data have been obtained to
Other Regimens
There are alternative regimens that are variations of the preferred regimen. As described below, alternative regimens may
be acceptable in certain clinical and/or public health situations
(see “Treatment in Special Situations”). An administration frequency of less than daily in the intensive phase of treatment is
generally not preferred.
Thrice-Weekly Dosing Throughout
In HIV-uninfected patients with noncavitary disease caused by
drug-susceptible organisms, thrice-weekly (ie, 3 times per
week) dosing throughout both intensive and continuation phases
of treatment by DOT may be considered when daily treatment is
not feasible or poorly tolerated. Thrice-weekly dosing has been
associated with higher rates of treatment failure, relapse, and acquired drug resistance in high-quality systematic reviews [36,
160]. The risks for these poor outcomes of treatment were higher
in HIV-infected patients (especially if not treated with antiretrovirals), and patients with cavitary disease or baseline drug resistance. Based on evidence supporting the recommendations
obtained through systematic reviews (see Supplementary Appendix B, Evidence Profiles 5,6,8–10), use of thrice-weekly therapy in
the intensive phase (with or without an initial 2 weeks of daily
therapy) may be considered in patients who are not HIV-infected
and are also at low risk of relapse (pulmonary tuberculosis caused
by drug-susceptible organisms, that at the start of treatment is
noncavitary and/or smear negative) (Recommendation 3b: conditional recommendation; low certainty in the evidence).
Twice-Weekly Dosing Throughout or Twice-Weekly Dosing After
2–3 Weeks of Daily Dosing
Twice-weekly dosing (ie, 2 times per week) either throughout
treatment or after an initial period of 2–3 weeks of daily therapy
is not generally recommended because of a lack of high-quality
evidence to support its use, and because in twice-weekly therapy, if doses are missed then therapy is equivalent to once weekly,
which is inferior (see “Once-Weekly Continuation Phase,”
below). However, some tuberculosis programs have reported
longstanding programmatic treatment success with an initial
daily regimen followed by twice-weekly therapy [161], and
this regimen remains in use by some public health programs
in the United States. In situations where daily or thrice-weekly
DOT therapy is difficult to achieve, use of twice-weekly therapy
after an initial 2 weeks of daily therapy may be considered for
patients who are not HIV infected and are also at low risk of
relapse ( pulmonary tuberculosis caused by drug-susceptible organisms, that at the start of treatment is noncavitary and/or
smear negative) (Recommendation 3c: conditional recommendation; very low certainty in the evidence) (see Supplementary
Appendix B, Evidence Profile 7).
Twice-Weekly Continuation Phase
Twice weekly treatment in the continuation phase has been
studied in clinical trials [36], and is used by US tuberculosis
control programs. Based on our systematic review, if intermittent therapy during the continuation phase is considered, then
we suggest use of thrice-weekly instead of twice-weekly therapy. (Recommendation 4b: conditional recommendation; low
certainty in the evidence) (see Supplementary Appendix B,
Evidence Profiles 5–8). As noted above for twice-weekly regimens, an advantage of a thrice-weekly regimen is that it allows for
the possibility of some doses being missed; with twice-weekly
therapy, if doses are missed then therapy is equivalent to once
weekly, which is inferior (see “Once-Weekly Continuation
Phase,” below).
Once-Weekly Continuation Phase
In clinical trials, once-weekly treatment with INH plus RPT 600
mg was less active than standard RIF-based treatment [9, 162]. In
the Tuberculosis Trials Consortium (TBTC) Study 22, characteristics independently associated with increased risk of failure or
relapse were sputum culture positivity at the end of intensive
phase, cavitation on chest radiograph, being underweight, bilateral pulmonary involvement, and being a non-Hispanic white
person [9]. Furthermore, relapse with rifamycin-monoresistant
tuberculosis occurred among HIV-infected tuberculosis patients treated with the once-weekly INH/RPT continuation
phase regimen [59]. In uncommon situations where more
than once-weekly DOT is difficult to achieve, once-weekly continuation phase therapy with INH 900 mg plus RPT 600 mg
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susceptibility studies demonstrate that the isolate is susceptible
to INH and RIF.
With respect to administration schedule, the preferred frequency is once daily for both the intensive and continuation
phases. Based on systematic reviews conducted to obtain evidence in support of this guideline (see Supplementary Appendix B, Evidence Profiles 5–10), we recommend the use of daily
rather than intermittent dosing in the intensive phase of therapy for drug-susceptible pulmonary tuberculosis (Recommendation 3a: strong recommendation; moderate certainty in the
evidence). For the continuation phase, based on systematic reviews conducted to obtain evidence in support of this guideline
(see Supplementary Appendix B, Evidence Profiles 5–10), we
recommend use of daily or thrice-weekly dosing for the continuation phase of therapy (Recommendation 4a: strong recommendation; moderate certainty in the evidence). Although
administration of antituberculosis drugs using DOT 5 days a
week has been reported in a large number of studies, it has
not been compared with 7-day administration in a clinical
trial. Nonetheless, on the basis of substantial clinical experience,
experts believe that 5-days-a-week drug administration by DOT
is an acceptable alternative to 7-days-a-week administration,
and either approach may be considered as meeting the definition of “daily” dosing. Patient-centered care, case management,
and DOT are discussed in the “Organization and Supervision of
Treatment” section of this guideline.
may be considered for use only in HIV-uninfected persons
without cavitation on chest radiography. Otherwise, we recommend against use of once-weekly therapy with INH 900 mg plus
RPT 600 mg (Recommendation 4c: strong recommendation;
high certainty in the evidence) (see Supplementary Appendix
B, Evidence Profile 11).
Alternative Regimen Composition
In some cases, either because of intolerance to first-line drugs or
the presence of monoresistance, an alternative regimen may be
required. If PZA cannot be included in the initial regimen, or
the isolate is determined to be resistant to PZA (an unusual circumstance, except for M. bovis and M. bovis var BCG), experts
recommend a regimen consisting of INH, RIF, and EMB for the
initial 2 months followed by INH and RIF for 7 months given
either daily or thrice weekly.
In scenarios in which EMB or INH cannot be used, the role of
moxifloxacin or levofloxacin has not been established through
clinical trials. Experts on occasion use moxifloxacin or levofloxacin in place of EMB during intensive phase in adults in whom
EMB cannot be used, or in place of INH throughout treatment
in adults in whom INH cannot be used (see Supplementary Appendix C: Drugs in Current Use for details on adverse effects of
fluoroquinolones, including QT prolongation).
There is no evidence that moxifloxacin or levofloxacin can be
used in place of a rifamycin or PZA while maintaining a
6-month treatment duration. If a rifamycin cannot be included
in the initial regimen due to resistance or intolerance, then a
regimen based on the principles described for treating drug-resistant tuberculosis is used. In situations in which several of the
first-line agents cannot be used because of intolerance, regimens
based on the principles described for treating drug-resistant tuberculosis are used.
Importantly, all alternative regimens using fluoroquinolones in
place of EMB or INH are 6 months or longer in duration. There is
definitive clinical trial evidence that 4-month daily regimens that
substitute moxifloxacin or gatifloxacin for EMB, or moxifloxacin
for INH, are significantly less effective than the preferred, standard daily 6-month treatment for drug-susceptible pulmonary
tuberculosis [5, 163, 164]. Therefore we recommend against the
routine use of 4-month fluoroquinolone-containing regimens
for treatment of drug-susceptible pulmonary tuberculosis.
A single randomized trial showed that a regimen of daily moxifloxacin/RIF/PZA/EMB for 2 months followed by once-weekly
1200 mg RPT + 400 mg moxifloxacin for 4 continuation phase
months had relapse rates similar to the standard 6-month regimen given daily [164]. Use of this regimen (including a daily
moxifloxacin-containing intensive phase) may be considered. It
is important to note that each dose of RPT was preceded by a
meal of 2 boiled eggs and slices of bread, provided to increase
the absorption of RPT. If this regimen is used, it is ideally
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Baseline and Follow-up Evaluations
Recommended baseline and follow-up evaluations for patients
suspected of having tuberculosis and treated with first-line medications are summarized in Figure 2. At baseline, patients in
whom pulmonary tuberculosis is suspected have 3 appropriate
sputum specimens collected for microscopic examination and
mycobacterial culture, and at least one specimen is tested with
a rapid molecular test. When the lung is the site of disease, 3
sputum specimens are obtained 8–24 hours apart [166, 167].
In patients who are not producing sputum spontaneously, induction of sputum using aerosolized hypertonic saline or bronchoscopy ( performed under appropriate infection-control
procedures) may be necessary to obtain specimens. Susceptibility testing for INH, RIF, EMB, and PZA is performed on an initial positive culture, regardless of the source. A rapid molecular
test for drug resistance is performed in patients at risk for drugresistant tuberculosis, and when resources permit, may be performed in all patients [15, 168]. Second-line drug susceptibility
testing should be done only in reference laboratories and is limited to specimens from patients who have had prior therapy,
have been in contact with a patient with known multidrug or
extensively drug-resistant tuberculosis, have suspected or demonstrated resistance to RIF and/or other first-line drugs, are unable to tolerate RIF, or who have positive cultures after >3
months of treatment [15, 168].
During treatment of patients with pulmonary tuberculosis, at
a minimum, a sputum specimen for AFB smear and culture are
obtained at monthly intervals until 2 consecutive specimens are
negative on culture. Duration of the continuation phase regimen hinges on the microbiological status at the end of the intensive phase of treatment, thus, obtaining sputum specimens at
the time of completion of 2 months of treatment is critical if
sputum culture conversion to negative has not already been
documented. For patients who had positive AFB smears at
the time of diagnosis, follow-up smears may be obtained at
more frequent intervals (for example, every 2 weeks until 2 consecutive specimens are negative) to provide an early assessment
of the response to treatment, especially for patients in situations
with high risk of transmission. On occasion, AFB-positive sputa
are culture-negative; this occurs most frequently among patients
with far-advanced cavitary tuberculosis after the first few
months of treatment. It is thought that AFB smear positive
(but culture-negative) sputa contain organisms that are dead
and that their presence is not a sign of treatment failure, even
when noted later in treatment. Dead organisms also can cause
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Fluoroquinolones (Moxifloxacin and Levofloxacin)
implemented within the context of program-based operational
research with suitable monitoring [165]. Of note, there is no evidence that a once-weekly continuation phase comprised of 1200
mg RPT + 400 mg moxifloxacin after 2 months of intensive
phase INH/RIF/PZA/EMB (ie, without moxifloxacin in place
of EMB in the intensive phase), would achieve similar outcomes.
Identification and Management of Patients at Increased Risk of Relapse
The culture result of a sputum specimen obtained at the completion of the intensive phase of treatment (2 months) has been
shown to correlate with the likelihood of relapse after completion of treatment for pulmonary tuberculosis, albeit with low
sensitivity [9, 44–46]. Cavitation on the initial chest radiograph
has also been shown to be a risk factor for relapse [9, 47]. In patients treated for 6 months, having both cavitation and a positive culture at completion of 2 months of therapy has been
associated with rates of relapse of approximately 20% compared
with 2% among patients with neither factor [9, 45].
The most effective means of decreasing the likelihood of relapse for patients at risk has not yet been determined by clinical
trials; however, indirect evidence from a controlled clinical trial
and an observational study among patients with pulmonary tuberculosis in Hong Kong showed that prolonging treatment decreased the rate of relapse [47, 169]. It has also been reported
that for patients at high risk of relapse, prolongation of the
once-weekly INH/RPT continuation phase from 4 to 7 months
resulted in a decreased rate of relapse [170].
In view of this evidence, for patients who have cavitation on
the initial chest radiograph and who have positive cultures at
completion of 2 months of therapy, expert opinion is to extend
the continuation phase with INH and RIF for an additional 3
months (ie, a continuation phase of 7 months in duration, corresponding to a total of 9 months of therapy).
Because patients who had either cavitation on the initial chest
radiograph or a positive culture at 2 months had an increased
rate of relapse [9, 45], patients with one or the other of these
risk factors are followed more closely and consideration given
to extending treatment duration if there are suggestions of a
poor response. Additional factors to be considered in deciding
to prolong treatment in patients with either cavitation or a positive culture at 2 months (but not both) might include being
>10% below ideal body weight; being a smoker; having diabetes,
HIV infection, or other immunosuppressing condition; or having extensive disease on chest radiograph [46, 48–52].
Interruptions in Therapy
Interruptions in therapy are common in the treatment of tuberculosis. When interruptions occur, the person responsible for
supervision must decide whether to restart a complete course
of treatment or simply to continue as intended originally. In general, the earlier the break in therapy and the longer its duration, the more serious the effect and the greater the need to
restart treatment from the beginning. Continuous treatment is
more important in the intensive phase of therapy when the bacillary population is highest and the chance of developing drug
resistance greatest. During the continuation phase, the number
of bacilli is much smaller and the goal of therapy is to kill the
persisting organisms. The duration of the interruption and the
bacteriologic status of the patient prior to and after the interruption are also important considerations.
There is no evidence upon which to base detailed recommendations for managing interruptions in treatment, and no recommendations will cover all of the situations that may arise. The approach
summarized in Table 6 (modified from the New York City Bureau
of Tuberculosis Control [171]) is presented as an example.
When interruptions are due to an interim loss of follow-up,
at the time the patient is returned to treatment, additional sputum are obtained for repeat culture and drug susceptibility testing. If the cultures are still positive, the treatment regimen is
restarted. If sputum cultures are negative, the patient could be
treated as having culture-negative tuberculosis and given an additional 4 months of INH and RIF chemotherapy, as long as the
original specimen was drug susceptible and the original intensive phase regimen included INH, RIF, and PZA. Regardless of
the timing and duration of the interruption, DOT is used subsequently. If the patient was already being managed with DOT,
additional measures will be necessary to ensure completion of
therapy. Consultation with an expert is advised to assist in managing treatment interruptions.
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a positive result on molecular tests; routine performance of molecular tests on follow-up sputum samples, after an initial positive test, is not useful.
Drug susceptibility tests are repeated on M. tuberculosis isolated in culture from sputum obtained after a patient has been on
treatment for ≥3 months. As described in the “Treatment Failure” section, patients who have M. tuberculosis isolated in culture
from sputum obtained after 4 months of treatment are considered as having failed treatment and managed accordingly.
For patients with positive cultures at diagnosis, a repeat chest
radiograph at completion of 2 months of treatment may be useful but is not essential. Tuberculosis programs often conduct a
chest radiograph at completion of therapy as it provides a baseline against which subsequent examinations can be compared,
but, as with the 2-month examination, it is not essential. When
the initial sputum cultures are negative, a presumptive diagnosis
can be made if radiographic improvement is noted, generally by
the time 2–3 months of treatment have been completed [93].
Thus, based on expert opinion, in patients with negative initial
cultures, a chest radiograph is recommended after 2–3 months
of treatment and at the completion of treatment to document
response to therapy. Generally, systematic follow-up after completion of therapy is not necessary.
In addition to the microbiological and imaging examinations
discussed here, other appropriate assessments and laboratory
tests are summarized in Figure 2. For patients with extrapulmonary tuberculosis, the frequency and kinds of evaluations will
depend on the sites involved and the ease with which specimens
can be obtained. Monitoring assessments for patients treated
with second-line drugs are listed by drug in Supplementary Appendix C: Drugs in Current Use.
Management of Common Adverse Effects
The determination of whether or not treatment has been completed is based on the total number of doses taken—not solely
on the duration of therapy (Table 2). Tuberculosis control program practice in the United States and in several European
countries is to administer all of the specified number of
doses for the intensive phase within 3 months and those for
the 4-month continuation phase within 6 months, so that
the 6-month regimen is completed within 9 months. If these
targets are not met, the patient must be considered to have interrupted therapy and be managed as described above
(Table 6).
Mild adverse effects usually can be managed with treatment directed at controlling the symptoms; severe effects usually require the offending drug(s) to be discontinued. If a drug is
permanently discontinued, then a replacement drug, typically
from a different drug class, is included in the regimen. Patients
with severe tuberculosis often require the initiation of an alternate regimen during the time the offending drug(s) are held.
Management of serious adverse effects often requires expert
consultation. The suggested practices listed below for handling
common adverse effects during treatment (ordered from most
to least common) are based on expert opinion.
PRACTICAL ASPECTS OF TREATMENT
Gastrointestinal Upset; Nausea, Vomiting, Poor Appetite,
Abdominal Pain
Drug Administration
Gastrointestinal reactions are common, especially early in therapy [53]. The optimum approach to management of epigastric
distress or nausea with tuberculosis drugs is not clear. To minimize symptoms, patients receiving SAT may take the medications at bedtime. Gastrointestinal intolerance not associated
with hepatotoxicity can be treated with antacids, which have
less impact on absorption or peak concentration of first-line
drugs than administration with food [54]. Some experts report
success with proton pump inhibitors for reducing gastrointestinal upset. Any combination of otherwise unexplained nausea,
vomiting, and abdominal pain is evaluated with a physical
examination and liver function tests, including ALT, AST, bilirubin, and alkaline phosphatase to assess for possible hepatotoxicity [55]. Alternatively, a light snack (low-fat food) such as a
cracker might suffice for some patients. Either option is preferable to splitting a dose or changing to a second-line drug. It is
important to note that divalent cations (calcium, iron, zinc) as
occur in some antacids and nutritional supplements are not coadministered with fluoroquinolones because they decrease absorption of the drug, possibly leading to treatment failure [179].
In general, tuberculosis drugs are administered together, at one
dosing so as to achieve maximal peak serum concentrations and
to facilitate DOT. Bioavailability of all of the drugs (except for
RPT) is greatest when taken on an empty stomach. The exception is RPT, for which bioavailability increases by up to 86%
with high-fat meals [172]. If medications need to be combined
with food or liquid for dosing, keep in mind that INH absorption decreases when combined with glucose or lactose; crushed
INH tablets in foods containing low glucose, such as sugar-free
pudding, are stable. However, crushed tablets mixed with food
should not be stored for later use [173]. The commercially prepared INH elixir uses sorbitol as the vehicle; sorbitol may also
cause diarrhea, thereby limiting its use.
Parenteral drug administration is indicated for severely ill patients who cannot take oral therapy, and may be useful for the
uncommon patient with suspected or documented malabsorption. Of the first-line drugs, parenteral preparations of INH and
RIF, as well as most fluoroquinolones, are available.
Fixed-Dose Combination Preparations
Clinical trials and a recent systematic review have concluded
that overall, there is no significant difference between fixeddose combinations (FDCs) and single-drug combinations
for key outcomes, including sputum smear or culture conversion, failure, relapse, death, serious adverse events, or
adverse events that lead to discontinuation of therapy
[174–178]. The patient-specific advantages to using FDC
drugs include ease of administration and the potential for
reducing medication errors. The key program and clinician-specific advantage of FDC formulations is the simplification of drug supply management ( procurement, storage,
and distribution) and simpler prescription writing. If
FDCs are used, clinicians should be aware that FDC and
non-FDC products have similar commercial names with different drug compositions, including Rifadin (RIF only),
Rifamate (INH and RIF), and Rifater (INH, RIF, and
PZA) (see Supplementary Appendix C).
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Rash
All antituberculosis drugs can cause a rash, the severity of which
determines management [180]. If the rash is mainly itchy without mucous membrane involvement or systemic signs such as
fever, treatment is symptomatic with antihistamines, and all antituberculosis medications can be continued. A petechial rash is
more concerning and suggests thrombocytopenia from a rifamycin (ie, RIF, RFB, RPT) hypersensitivity [181]. If the platelet
count is low, the rifamycin is permanently stopped and the
platelet count closely monitored until definite improvement is
noted. Drugs are also stopped if the patient has a generalized
erythematous rash. Fever and/or mucous membrane involvement suggests Stevens-Johnson syndrome, toxic epidermal necrosis, or drug reaction with eosinophilia and systemic
symptoms syndrome or drug hypersensitivity syndrome. Hypersensitive reactions to multiple antituberculosis drugs have
been noted, particularly in persons with HIV infection [180].
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Definition of Completion of Therapy
Drug Fever
Drug fever is essentially a diagnosis of exclusion. Other causes of
fever such as tuberculosis (fever may persist 2 months or longer
into treatment) [183, 184]; paradoxical reaction, especially in
HIV-infected patients (See “HIV Infection”) [185–187]; and
superinfection must be excluded. Patients with drug fever generally feel well despite body temperatures ≥39°C. Drug fever does
not follow a specific pattern and eosinophilia need not be present.
Stopping drugs usually resolves the fever within 24 hours. Once
afebrile, the patient should restart drugs individually every 2–3
days, similar to the approach to drug rechallenge for rash.
Hepatotoxicity
Drug-induced hepatitis is the most frequent serious adverse reaction to the first-line drugs (see “Hepatic Disease” and Supplementary Appendix C). INH, RIF, and PZA can cause druginduced liver injury, which is suspected when the ALT level is
≥3 times the upper limit of normal in the presence of hepatitis
symptoms, or ≥5 times the upper limit of normal in the absence
of symptoms [56]. If the ALT level is <5 times the upper limit of
normal, toxicity can be considered mild, an ALT level 5–10
times normal defines moderate toxicity, and an ALT level >10
times normal (ie, >500 IU) is severe.
An asymptomatic increase in ALT concentration occurs in
nearly 20% of patients treated with the standard 4-drug regimen
[188, 189]. In the absence of symptoms, therapy should not be
altered because of modest asymptomatic elevations of ALT,
but the frequency of clinical and laboratory monitoring should
be increased. In most patients, asymptomatic ALT elevations
resolve spontaneously. However, if ALT levels are ≥5 times the
upper limit of normal (with or without symptoms) or ≥3 times
normal in the presence of symptoms, hepatotoxic drugs are
stopped immediately and the patient is evaluated carefully. Similarly, a significant increase in bilirubin and/or alkaline phosphatase is cause for a prompt evaluation; disproportionate increases
in bilirubin and alkaline phosphatase (as compared to increases
in serum ALT) may be seen with RIF hepatotoxicity [56].
Other causes of abnormal liver tests must be excluded before
diagnosing drug-induced hepatitis (Table 7). If ALT levels are
consistent with hepatotoxicity, all hepatotoxic drugs must be
stopped and serum ALT and prothrombin time or international
normalized ratio (INR) levels followed until levels return to
baseline. Consult a liver specialist if the patient’s clinical or laboratory status continues to worsen.
Once the ALT concentration returns to <2 times the upper
limit of normal, antituberculosis medications are restarted individually (see [56] for additional details). In patients with elevated baseline ALT from preexisting liver disease, drugs are
restarted when the ALT returns to near-baseline levels. The optimal approach to reintroducing tuberculosis treatment after
hepatotoxicity is not known [57, 58]; however, most tuberculosis programs use sequential reintroduction of drugs. Because
RIF is much less likely to cause hepatotoxicity than INH or
PZA, it is restarted first. If there is no increase in ALT after approximately 1 week, INH may be restarted. PZA can be started 1
week after INH if ALT does not increase. If symptoms recur or
ALT increases, the last drug added should be stopped. If RIF
and INH are tolerated and hepatitis was severe, PZA can be assumed to be responsible and is discontinued. In this last circumstance, depending on the number of doses of PZA taken,
severity of disease, and bacteriological status, the total duration
of therapy might be extended to 9 months.
Optic Neuritis
EMB-related visual impairment during treatment of active tuberculosis has been estimated to occur in 22.5 per 1000 persons
(2.25%) receiving EMB at standard doses [190] (see Supplementary Appendix C). The onset of optic neuritis is usually >1
month after treatment initiation but can occur within days
[191, 192]. The opinion of experts is that baseline visual acuity
(Snellen test) and color discrimination tests followed by monthly color discrimination tests are performed during EMB use. To
avoid permanent deficits, EMB is promptly discontinued if visual abnormalities are found. If vision does not improve with
cessation of EMB, experts recommend stopping INH as well,
as it is also a rare cause of optic neuritis [193].
Drug–Drug Interactions
Interactions Affecting Antituberculosis Drugs
Drug–drug interactions can change the concentrations of the
drugs involved. Relatively few interactions substantially change
antituberculosis drug concentrations; much more often, the antituberculosis drugs cause clinically relevant changes in the concentrations of other drugs. The exceptions to this general rule
are RFB and the fluoroquinolones.
• Inhibitors of CYP3A increase the serum concentrations of
RFB and one of its metabolites (25-O-desacetyl-rifabutin),
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Some experts manage severe systemic reactions in the inpatient
setting, using an interval of several days between drug rechallenges, closely monitoring markers of hypersensitivity (such
as rash, fever, transaminitis, eosinophilia, pruritus, etc). If any
of these markers develop, then the drug is stopped and identified as the offender, eliminating it from the regimen. Systemic
corticosteroids may be used to treat severe systemic reactions.
Using steroids to treat systemic reactions, even in the setting
of severe tuberculosis, has not worsened outcomes [182].
When the rash has substantially improved, medications can
be restarted individually at intervals of 2–3 days. RIF is restarted
first (the most potent drug), followed by INH, then EMB or
PZA. If the rash recurs, the last drug added is stopped. If the
first 3 drugs have been restarted without a rash, the fourth
drug is not restarted unless the rash was mild and that drug essential. Research evaluating drug provocation tests or drug desensitization strategies is needed [180].
Antituberculosis Drugs Affecting Other Drugs
Drug Interactions Due to Rifamycins
Most of the clinically relevant drug–drug interactions involving
the antituberculosis drugs are due to the effect of the rifamycins
(RIF, RFB, and RPT) on the metabolism of other drugs [205]. All
of the rifamycins are inducers of a variety of metabolic pathways,
particularly those involving the various isozymes of the cytochrome P450 (CYP) system [206]. By inducing the activity of
metabolic enzymes, rifamycins decrease the serum concentrations of many drugs, sometimes to subtherapeutic levels [207].
RIF is the most potent enzyme inducer and RFB the least,
while RPT’s potency depends on its frequency of administration
[208, 209]. Daily RPT is at least as potent as daily RIF, while onceweekly RPT (as used in combination with INH for latent tuberculosis infection [210]) has limited effects on other drugs.
The well-described, clinically relevant, drug–drug interactions
involving the rifamycins are presented in Table 8 [206, 211]; however, many possible interactions involving the rifamycins have
not been fully investigated and additional clinically relevant interactions undoubtedly will be described. Therefore, it is important to check all concomitant medications for possible, as well as
confirmed, drug–drug interactions with rifamycins.
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Rifamycin inductive effects typically take approximately 1–2
weeks to reach steady state after the rifamycin is started, and inductive effects typically resolve over approximately 2 weeks after
the rifamycin is discontinued [209]. If the dose of a medication
is increased to compensate for the effect of a rifamycin, it is critical to reduce the dose within 2 weeks after the rifamycin is discontinued and its inductive effect resolves.
RFB can be used in place of RIF if there is an unacceptable
drug–drug interaction between RIF and another drug such as
cyclosporine [212, 213] and most of the HIV-1 protease inhibitors [208, 214, 215]. All the rifamycins may cause unacceptable
decreases in the serum concentrations of certain drugs such as
itraconazole [216–218].
Drug Interactions Due to INH
INH is a relatively potent inhibitor of several CYP isozymes
[219, 220] and increases concentrations of some drugs to the
point of toxicity such as the anticonvulsants phenytoin [221,
222] and carbamazepine [223, 224]. INH also increases concentrations of benzodiazepines metabolized by oxidation, such as
diazepam [225] and triazolam, but not those metabolized by
conjugation, such as oxazepam [226]. Of note, the inductive effect of RIF on CYP isozymes outweighs the inhibitory effect of
INH, so that the overall effect of combined therapy with RIF
and INH is a decrease in the concentrations of drugs such as
phenytoin [227] and diazepam [225].
INH may increase toxicity of other drugs—acetaminophen
[228], valproate [229], serotonergic antidepressants [230], warfarin [231], and theophylline [232]—but these potential interactions have not been well studied. A possible interaction between
INH and disulfiram was initially described [233]; however, a retrospective study found that disulfiram was safe when added to
intermittent, directly observed INH-containing tuberculosis
treatment [234].
Drug Interactions Due to the Fluoroquinolones
Ciprofloxacin [235] inhibits the metabolism of theophylline and
can cause clinical theophylline toxicity [236]; however, levofloxacin [237], gatifloxacin [238], and moxifloxacin [239] do not affect theophylline metabolism.
Useful Websites Regarding Drug Interactions
Useful websites regarding drug interactions (tuberculosis/HIV
and other) are available through the following hyperlinks:
AIDSinfo, Centers for Disease Control and Prevention,
University of California San Francisco, University of
Liverpool, Indiana University, and University of Maryland.
Therapeutic Drug Monitoring
TDM generally consists of measurements of drug concentrations in serum specimens typically collected at 2 and 6 hours
after a dose of the drug, or drugs, in question. Other sampling
times may be used for selected situations. Blood samples are
centrifuged; the serum is harvested and frozen, and then
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sometimes producing toxicities. For example, administering ritonavir, a very potent CYP3A inhibitor, with the standard daily
dose of RFB (300 mg) increases the serum concentrations of
RFB (4-fold) and 25-O-desacetyl-rifabutin (35-fold) [194] and
is associated with increased rates of leukopenia, arthralgias, skin
discoloration, and anterior uveitis [195, 196]. Conversely, administering RFB with a CYP3A inducer such as efavirenz or
phenytoin may decrease RFB concentrations [197], and this
may lead to clinical failures and the selection of rifamycin-resistant M. tuberculosis. Recommendations for RFB dose adjustments are available at AIDSinfo, and at the CDC website
(http://www.cdc.gov/tb/publications/guidelines/tb_hiv_drugs/
default.htm). Because interactions are complex and given the
rapid emergence of new data on antiretroviral therapy (ART),
the management of HIV-related tuberculosis cases should involve a physician with experience in this field.
• Absorption of the fluoroquinolones is markedly decreased
by ingestion of medications containing divalent cations (calcium, iron, zinc) including antacids [198, 199]; supplements or vitamins containing calcium, iron, or zinc [200]; sucralfate [201];
and the chewable tablet formulation of didanosine [202]. These
drug interactions can be avoided by ingesting medications containing divalent cations at least 2 hours apart from fluoroquinolones [203]. In addition, moxifloxacin serum concentrations
are decreased by 25%–30% in the presence of RIF due to the
induction of phase II metabolic enzymes (sulfation and glucuronidation) [204]. RPT and RFB also may decrease moxifloxacin
serum concentrations, though the clinical significance of these
drug–drug interactions in individual patients is uncertain.
Table 9. Conditions or Situations in Which Therapeutic Drug Monitoring
May Be Helpful
Poor response to tuberculosis treatment despite adherence and fully
drug-susceptible Mycobacterium tuberculosis strain
Severe gastrointestinal abnormalities: severe gastroparesis, short bowel
syndrome, chronic diarrhea with malabsorption
Drug–drug interactions
Impaired renal clearance: renal insufficiency, peritoneal dialysis, critically ill
patients on continuous renal replacement
HIV infection
Diabetes mellitus
Treatment using second-line drugs
Abbreviation: HIV, human immunodeficiency virus.
Both the CDC and WHO recommend routine HIV testing
and counseling to all patients with presumptive and diagnosed
tuberculosis [253, 254]. Treatment of tuberculosis in patients
with HIV infection has several important differences compared
with treatment of patients who do not have HIV infection.
These differences include the need for ART, the potential for
drug–drug interactions, especially between the rifamycins and
antiretroviral agents, paradoxical reactions that may be interpreted as clinical worsening, and the potential for developing
resistance to rifamycins when using intermittent tuberculosis
therapy. Because of the strong epidemiological association between HIV and tuberculosis infections and the clinical considerations discussed below, all individuals diagnosed with
tuberculosis are tested for HIV infection.
Clinical Trials of Treatment for Tuberculosis in HIV-Infected Patients
TREATMENT IN SPECIAL SITUATIONS
HIV Infection
PICO Question 5: Does extending treatment beyond 6 months improve
outcomes compared to the standard 6-month treatment regimen
among pulmonary tuberculosis patients coinfected with HIV?
Recommendation 5a: For HIV-infected patients receiving ART, we
suggest using the standard 6-month daily regimen consisting of an
intensive phase of 2 months of INH, RIF, PZA, and EMB followed by a
continuation phase of 4 months of INH and RIF for the treatment of
drug-susceptible pulmonary tuberculosis (conditional
recommendation; very low certainty in the evidence).
Recommendation 5b: In uncommon situations in which HIV-infected
patients do NOT receive ART during tuberculosis treatment, we
suggest extending the continuation phase with INH and RIF for an
additional 3 months (ie, a continuation phase of 7 months in duration,
corresponding to a total of 9 months of therapy) for treatment of drugsusceptible pulmonary tuberculosis (conditional recommendation; very
low certainty in the evidence).
PICO Question 6: Does initiation of ART during tuberculosis treatment
compared to at the end of tuberculosis treatment improve outcomes
among tuberculosis patients coinfected with HIV?
Recommendation 6: We recommend initiating ART during tuberculosis
treatment. Antiretroviral therapy should ideally be initiated within the
first 2 weeks of tuberculosis treatment for patients with CD4 counts
<50 cells/µL and by 8–12 weeks of tuberculosis treatment initiation for
patients with CD4 counts ≥50 cells/µL (strong recommendation; high
certainty in the evidence). Note: an exception is patients with HIV
infection and tuberculous meningitis (see Immune Reconstitution
Inflammatory Syndrome).
There have been a number of prospective studies, including 4
randomized controlled trials, of 6-month regimens for the treatment of pulmonary tuberculosis in patients with HIV infection
for which recurrence data were reported [59, 247, 248, 255–257].
All reported a good early clinical response to tuberculosis therapy. The time required for sputum culture conversion from positive to negative and tuberculosis treatment failure rates were
similar to these indices of treatment efficacy in patients without HIV infection. Recurrence of tuberculosis after treatment
completion may be due to relapse or reinfection. Relapse of
tuberculosis in HIV-infected individuals is associated with nonadherence to treatment, use of intermittent regimens, and with
low plasma drug concentrations, all of which also contribute to
the emergence of rifamycin resistance [9, 59–62, 250]. Reinfection with a new strain of M. tuberculosis is well documented in
patients with HIV infection and occurs in settings where transmission is more common, such as in countries with high rates of
tuberculosis or congregate living facilities (eg, prisons or hospitals) where infection control is inadequate. A study in Democratic Republic of the Congo (formerly Zaire) found that
extending treatment from 6 to 12 months reduced the recurrence rate from 9% to 3% [255]. A randomized trial in Haiti
found that 6-month treatment with a standard regimen
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shipped frozen to a reference laboratory. Quality-assured laboratories in the United States and in Europe offer assays for some
or all of the antituberculosis drugs [240, 241]. There are no prospective randomized trials that clearly define the role of TDM
for antituberculosis drugs. As such, opinions vary regarding
the utility of TDM. Experts generally use TDM as a specialized tool, providing insight into the adequacy of drug dosing
[242]. For example, serum concentrations of tuberculosis
drugs among children and HIV-infected patients with tuberculosis are frequently lower than those in healthy volunteers,
at the same (mg/kg body weight) dose [243–246]. In some
reports, lower concentrations did not have an impact on
treatment response or cure [247–249]. Other reports have
found an association between low drug exposure and failure,
relapse, and acquired rifamycin resistance [250–252]. TDM
cannot predict who will be cured, fail, or relapse; however,
it does allow for timely, informed decisions regarding the
need for dose adjustment when necessary. Experts suggest
that TDM may be particularly helpful in situations in
which drug malabsorption, drug underdosing, or clinically
important drug–drug interactions are suspected (Table 9).
Examples of situations in which TDM may be useful include
(1) patients with delayed sputum conversion or treatment
failure not explained by nonadherence or drug resistance;
(2) patients with medical conditions (eg, reduced renal function) that are suspected of leading to subtherapeutic or toxic
drug concentrations; and (3) patients undergoing treatment
for drug-resistant tuberculosis.
Table 10.
Suggested Pyrazinamide Doses, Using Whole Tablets, for Adults Weighing 40–90 kga
Weight, kgb,c
40–55
56–75
76–90
Daily (mg/kg)
Regimen
1000 mg (18.2–25.0)
1500 mg (20.0–26.8)
2000 mg (22.2–26.3)
Thrice weekly (mg/kg)
1500 mg (27.3–37.5)
2500 mg (33.3–44.6)
3000 mg (33.3–39.5)
Twice weekly (mg/kg)
2000 mg (36.4–50.0)
3000 mg (40.0–53.6)
4000 mg (44.4–52.6)
a
With normal renal function.
b
Based on estimated lean body weight. Optimal doses for obese patients are not established.
c
Numbers in parentheses are the calculated mg/kg doses for patients at the highest and lowest body weights in the weight band.
Table 11.
However, it is important to note that the majority of these studies were reports on nonrandomized cohorts, most were completed prior to the era of routine antiretroviral use, many tested
intermittent regimens, and few distinguished between reinfection and relapse (see Supplementary Appendix B). As discussed
below, based on data that show significant reductions in mortality and AIDS-defining illnesses, patients with HIV infection and
tuberculosis should receive ART in conjunction with daily antituberculosis medications. For HIV-infected patients receiving
ART, we suggest using the standard 6-month daily regimen consisting of an intensive phase of 2 months of INH, RIF, PZA, and
EMB followed by a continuation phase of 4 months of INH and
RIF for the treatment of drug-susceptible pulmonary tuberculosis (Recommendation 5a: conditional recommendation; very low
certainty in the evidence) (see Supplementary Appendix B,
Evidence Profile 12). In the uncommon situation in which an
HIV-infected patient does NOT receive ART during tuberculosis
treatment, we suggest extending the continuation phase with
INH and RIF for an additional 3 months (ie, a continuation
phase of 7 months in duration, corresponding to a total of 9
months of therapy) for treatment of drug-susceptible pulmonary
tuberculosis (Recommendation 5b: conditional recommendation; very low certainty in the evidence). As is noted for drugsusceptible pulmonary tuberculosis in patients without HIV coinfection, the continuation phase is extended in specific situations that are known to increase risk for relapse (see
“Identification and Management of Patients at Increased Risk
of Relapse”), as well as for selected extrapulmonary sites of disease, namely tuberculous meningitis, and bone, joint, and spinal
tuberculosis (see “Extrapulmonary Tuberculosis”).
Suggested Ethambutol Dosages, Using Whole Tablets, for Adults Weighing 40–90 kga
Weight, kgb,c
40–55
56–75
76–90
Daily (mg/kg)
Regimen
800 mg (14.5–20.0)
1200 mg (16.0–21.4)
1600 mg (17.8–21.1)
Thrice weekly (mg/kg)
1200 mg (21.8–30.0)
2000 mg (26.7–35.7)
2400 mg (26.7–31.6)
Twice weekly (mg/kg)
2000 mg (36.4–50.0)
2800 mg (37.3–50.0)
4000 mg (44.4–52.6)
a
With normal renal function.
b
Based on estimated lean body weight. Optimal doses for obese patients are not established.
c
Numbers in parentheses are the calculated mg/kg doses for patients at the highest and lowest body weights in the weight band.
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followed by 12 months of INH preventive therapy reduced recurrences from 7.8 per 100 person-years to 1.4 per 100 personyears [258]. Therefore, in areas where reinfection is likely, the
opinion of experts is that secondary preventive therapy with
INH may be justified.
In regard to duration of treatment for drug-susceptible pulmonary tuberculosis in the presence of HIV infection, the standard regimen currently used worldwide is the 6-month regimen
consisting of an intensive phase of 2 months of INH, RIF, PZA,
and EMB followed by a continuation phase of 4 months of INH
and RIF [10, 67, 98]. There is, however, a paucity of data on the
optimal duration of tuberculosis treatment for HIV-infected patients receiving highly active antiretroviral therapy (HAART),
though it is widely believed that the standard 6-month regimen
is effective and achieves tuberculosis cure rates comparable to
those reported for HIV-uninfected patients. In the TB-HAART
(Early Versus Delayed Initiation of HAART for HIV-Infected
Adults With Newly Diagnosed Pulmonary Tuberculosis) trial,
patients with CD4 counts ≥220 cells/µL were randomized on
timing of ART initiation [259]. All patients were treated with
the standard 6-month regimen for tuberculosis and were followed for 12 months. Among patients who completed treatment, recurrence of tuberculosis occurred in 2.0%, providing
indirect but supportive evidence that a 6-month regimen is effective in HIV-infected patients receiving ART. In our updated
systematic review of randomized trials and cohort studies comparing various durations of tuberculosis therapy (6 months vs 8
months or longer), most of which were conducted prior to the
era of HAART, we found that the risk of recurrence is lower
when the continuation phase of treatment is extended.
relative risk of death compared with patients receiving deferred
ART (5.6 per 100 person-years vs 12.1 per 100 person-years).
The benefit of ART given immediately or early was seen in patients with CD4 lymphocyte counts <200 cells/µL and 200–500
cells/µL. Subsequently, the Cambodian Early Versus Late Introduction of Antiretrovirals trial showed that initiation of ART
within 2 weeks of starting antituberculosis treatment reduced
mortality rate by 34% compared to starting after 8 weeks, in a
population of HIV-infected individuals with very low CD4 cell
counts (median, 25 cells/µL) [261]. The Immediate vs Deferred
Start of Anti-HIV Therapy in HIV-Infected Adults Being Treated for Tuberculosis (STRIDE) trial and the second phase of the
SAPiT study, both of which compared immediate (2 weeks)
with early (8–12 weeks) ART for HIV-infected patients beginning antituberculosis treatment, showed that immediate therapy
was associated with significantly lower rates of progression of
HIV disease to new AIDS-defining conditions or death compared to early therapy for patients with CD4 counts <50 cells/
µL, but starting ART within 2 weeks was not superior to starting
at 8 weeks for individuals with CD4 counts >50 cells/µL [262,
263]. All of these studies also showed that immediate ART was
associated with significantly greater rates of IRIS, most of which
was not severe.
More recently, the TB-HAART trial found that among patients with HIV and CD4 counts >220 cells/µL, immediate initiation of ART did not reduce mortality compared with waiting
until completion of 6 months of antituberculosis treatment to
start ART [259]. Unlike the SAPiT and STRIDE trials, however,
TB-HAART did not assess progression of HIV disease as a study
endpoint. Although the study did not find a survival benefit in
patients with HIV-related tuberculosis and higher CD4 lymphocyte counts, it did confirm the safety of co-treatment of tuberculosis and HIV infection and documented good outcomes of
tuberculosis treatment in those patients receiving dual therapy.
We performed a systematic review and meta-analysis to obtain evidence in support of this guideline, which included the 4
trials above and 4 additional studies (see Supplementary Appendix B, Evidence Profile 13) [259–266]. We found that the
overall reduction in mortality with ART initiated during treatment of tuberculosis was 24% (risk ratio, 0.76; 95% confidence
interval [CI], .57–1.01). The overall risk of HIV disease progression was reduced by 34% with early or immediate ART (4 studies: risk ratio, 0.66; 95% CI, .47–.91). Initiation of ART during
antituberculosis therapy was associated with an increased risk of
IRIS (8 studies: risk ratio, 1.88; 95% CI, 1.31–2.69). Our metaanalysis identified no increase in the risk of other adverse events
or poor outcome of tuberculosis therapy. Consequently, on the
basis of high certainty in the evidence that the benefits outweigh
the harms, we recommend that patients with tuberculosis and
HIV infection receive ART during antituberculosis treatment.
Antiretroviral therapy should ideally be started within 2 weeks
for those patients with a CD4 count <50 cells/µL and by 8–12
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Use of intermittent tuberculosis treatment regimens in HIVinfected patients has been associated with high rates of relapse
and the emergence of drug resistance. In TBTC Study 22, patients with HIV infection who received once-weekly RPT and
INH or twice-weekly RIF and INH in the continuation phase
had an unacceptably high rate of relapse: 5 of 30 (16.7%) in
the former and 3/31 (9.8%) in the latter group [9]. In addition,
for those receiving weekly therapy, 4 patients relapsing had acquired rifamycin resistance, which was associated with low
serum concentrations of INH and was presumably the result
of unopposed rifamycin exposure [59]. In a trial of RFB-based
antituberculosis therapy in combination with antiretroviral
drugs, patients treated with twice-weekly RFB had a relapse
rate of 5.3%, but 8 of 9 relapses had acquired rifamycin resistance [60]. Relapse and resistance were associated with low
CD4 lymphocyte counts, as all recurrences occurred in patients
with baseline CD4 lymphocyte counts <100 cells/µL. In the
pharmacokinetic substudy of the trial, lower plasma concentrations of RFB and INH were identified as key risk factors for acquiring rifamycin resistance [250]. More recently, the use of a
thrice-weekly RIF-based regimen during the intensive and continuation phases of treatment was associated with a higher
rate of relapse and emergence of rifamycin resistance in HIVinfected individuals not receiving antiretrovirals compared
with HIV-infected patients also receiving antiretrovirals or
HIV-uninfected patients [62]. Based in part on systematic reviews conducted to obtain evidence in support of this guideline,
our expert opinion is that treatment of HIV-related tuberculosis
be given daily in both the intensive and continuation phases to
avoid recurrent disease and the emergence of rifamycin resistance (see “Recommended Treatment Regimens”).
Mortality among patients with HIV and tuberculosis is high,
principally due to complications of immunosuppression and
occurrence of other HIV-related opportunistic diseases. In
this regard, the value of co-trimoxazole (trimethoprim-sulfamethoxazole) prophylaxis in reducing morbidity and mortality
in HIV-infected patients with newly diagnosed tuberculosis is
well established [63–65]. Whereas the WHO recommends routine co-trimoxazole prophylaxis for all HIV-infected people
with active tuberculosis disease regardless of the CD4 cell
count [66], in high-income countries, co-trimoxazole prophylaxis is primarily used in tuberculosis patients coinfected with
HIV with CD4 counts <200 cells/µL [67]. The use of ART during tuberculosis treatment in persons with HIV infection also
reduces mortality rates significantly for those with advanced
HIV disease and decreases the risk of developing AIDS-related
conditions. The Starting Antiretroviral therapy at Three Points
in Tuberculosis (SAPiT) trial randomized patients with tuberculosis and HIV with CD4 lymphocyte counts <500 cells/µL
to initiate ART after 2 weeks (immediate), 8 weeks (early), or
6 months (deferred) of tuberculosis treatment [260]. Patients receiving immediate or early ART had a 56% reduction in the
weeks for those with a CD4 count ≥50 cells/µL (Recommendation 6: strong recommendation; high certainty in the evidence).
An important exception is HIV-infected patients with tuberculous meningitis, in whom ART should not be initiated in the
first 8 weeks of antituberculosis therapy (see “Immune Reconstitution Inflammatory Syndrome”).
Concurrent Administration of Antiretrovirals and Rifamycins
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Interaction of RIF with antiretroviral agents is a major treatment concern (see “Drug–Drug Interactions”). RIF is a potent
inducer of drug metabolizing enzymes in the CYP family and
drug transporters such as P-glycoprotein [206]. Coadministration of RIF with drugs metabolized or transported by these
compounds may lead to reductions in exposure and loss of efficacy [207]. HIV protease inhibitors are metabolized by
CYP3A4, and their concomitant administration with RIF
leads to >80% reductions in serum concentrations of the protease inhibitors and loss of therapeutic benefit. RIF also increases
the metabolism of nonnucleoside reverse transcriptase inhibitors (NNRTIs), integrase strand transfer inhibitors (INSTIs),
and CCR-5 inhibitors. Detailed recommendations for coadministration of rifamycins and antiretroviral drugs have been published by the CDC, and we support these guidelines [215].
The NNRTI efavirenz is the most widely used antiretroviral
drug and is the preferred initial treatment for HIV (in combination with other antiretroviral drugs) in many countries. Coadministration of RIF-containing antituberculosis regimens
with efavirenz results in satisfactory antiviral efficacy, despite reductions in trough efavirenz concentrations [267, 268]. INH is
an inhibitor of an alternative, minor CYP pathway involved in
efavirenz metabolism. Thus, when INH and RIF are given to individuals with genetic polymorphisms associated with slow efavirenz clearance, efavirenz serum concentrations may reach
supratherapeutic levels. The US Food and Drug Administration
(FDA) recommends that the dosage of efavirenz be increased
from 600 mg/day to 800 mg/day for patients weighing >60 kg
on the basis of pharmacokinetic modeling of data from healthy
volunteers; however, data from clinical studies, including the
STRIDE study, do not support this advice [267, 268], and
many other experts believe that efavirenz should be administered at the standard dose of 600 mg/day in patients receiving
standard dose RIF-containing regimens. A treatment-shortening
trial evaluating high-dose daily RPT used in combination with
efavirenz-based ART for HIV-infected patients is under way
(ClinicalTrials.gov identifier: NCT02410772).
The NNRTI nevirapine has also been studied as an alternative
treatment for HIV-infected patients with tuberculosis [269].
However, RIF also reduces concentrations of nevirapine, a drug
that induces its own metabolism [270]. Due to this autoinduction, nevirapine is initially given at a dosage of 200 mg/day for
2 weeks and then increased to 200 mg/twice daily or 400 mg/
once daily. When nevirapine is started during antituberculosis
treatment, use of the 200 mg daily lead-in dose can lead to subtherapeutic concentrations, loss of antiviral efficacy, and emergence of drug resistance [271–273]. Therefore, expert opinion
is that if nevirapine is used during treatment with RIF, the initiation dose should be at the full 400-mg daily dosage (200 mg
twice daily or 400 mg daily).
The INSTIs are now considered first-line agents for HIV
infection in the United States and in Europe. Raltegravir and
dolutegravir are metabolized mainly by uridine 5′-diphosphoglucuronosyltransferase 1A1 [274, 275], and concomitant use of
RIF reduces trough concentrations significantly. The “Raltegravir
for the treatment of patients co-infected with HIV and tuberculosis” (Reflate TB) trial showed that coadministration of RIFbased antituberculosis treatment and raltegravir at 400 mg/twice
daily was associated with similar antiviral effectiveness compared
to coadministration of RIF-based antituberculosis treatment and
raltegravir 800 mg twice daily; both were somewhat more effective than efavirenz 600 mg daily [274]. However, pharmacokinetic data favor increasing the dose to 800 mg twice daily, and expert
opinion in the United States favors this strategy [276]. Pharmacokinetic studies demonstrate that coadministration of RIF and
dolutegravir at a dosage of 50 mg given twice daily results in adequate trough concentrations of dolutegravir [275]. A clinical
study of patients with active tuberculosis given RIF and dolutegravir is under way (ClinicalTrials.gov identifier: NCT02178592).
RFB is less potent an inducer of CYP isoenzymes and may be
used in patients receiving ART; however, RFB itself is metabolized by CYP3A enzymes, and the antiretroviral agent ritonavir
(used to boost protease inhibitor levels) inhibits CYP3A enzymes, which increases concentrations of RFB. High concentrations of RFB are associated with an increased risk of uveitis and
other toxicities, so dose adjustment of the standard RFB dosage
of 300 mg daily is necessary [215].
Expert opinion is to use RFB at a dose of 150 mg/day or 300
mg every other day as part of a combination antituberculosis
regimen for patients receiving ritonavir-boosted protease inhibitors [214]. In patients receiving dose-adjusted RFB because of
concomitant protease inhibitor use, frequent assessment of adherence to both medicines is prudent, as discontinuation of the
protease inhibitor while continuing dose-adjusted RFB (ie, in
the context of DOT tuberculosis therapy but self-administered
antiretrovirals) would be expected to result in subtherapeutic
concentrations of the rifamycin, possibly with consequent
poor treatment outcome and acquired rifamycin resistance. Efavirenz is also a CYP3A inducer, and when RFB is coadministered with this agent the RFB dosage needs to be increased to
600 mg/day; however, indications to use RFB instead of RIF
in patients receiving efavirenz are rare.
When RFB is not available and treatment with a protease inhibitor is required because of resistance to NNRTIs and/or
INSTIs, use of RIF with a lopinavir/ritonavir regimen may be
attempted. For adults, this generally entails increasing the
dosage of lopinavir/ritonavir from 400 mg/100 mg twice daily
to 800 mg/200 mg twice daily over 2 weeks. This so-called
“double dosing” of boosted lopinavir may result in hepatotoxicity and careful clinical monitoring is necessary [215]. Alternatively, “super boosting” of lopinavir, though poorly tolerated in
adults, is sometimes effective, especially in children. In this instance, the dosage of lopinavir is maintained at 400 mg twice
daily, but ritonavir dosage is increased from 100 mg twice
daily to 400 mg twice daily. Super boosting of ritonavir is poorly
tolerated in adults, however, and the double-dosing strategy is
preferred. These complicated interactions underscore the importance of expert consultation in treating individuals with concurrent HIV and tuberculosis infections. For situations
involving complex drug–drug interactions, some clinicians prefer to measure the concentrations of the interacting drugs, and
to dose these drugs based upon individualized data [242].
Transient worsening of tuberculosis symptoms and lesions in
response to antituberculous therapy has previously been reported in HIV-uninfected patients [277]. Patients with HIV infection and tuberculosis are at an increased risk of developing
paradoxical worsening of symptoms, signs, or clinical manifestations of tuberculosis after beginning antituberculosis and
antiretroviral treatments. These reactions develop as a consequence of reconstitution of immune responsiveness brought
about by ART, and are designated as the IRIS. Tuberculosis
IRIS has been noted to be more common in participants with
earlier ART initiation and CD4+ lymphocyte counts <50 cells/
µL. In the STRIDE study, IRIS occurrence was infrequent at
7.6%. When tuberculosis IRIS occurred, the majority (69%) of
cases were mild to moderate in severity; however, 31% were hospitalized with tuberculosis IRIS and more than half received
corticosteroids [68]. Signs of IRIS may include high fevers,
worsening respiratory symptoms, increase in size and inflammation of involved lymph nodes, new lymphadenopathy, expanding central nervous system (CNS) lesions, worsening of
pulmonary parenchymal infiltrations, new or increasing pleural
effusions, and development of intra-abdominal or retroperitoneal abscesses [69]. Such findings are attributed to IRIS only
after excluding other possible causes, especially tuberculosis
treatment failure from drug-resistant tuberculosis or another
opportunistic disease, such as non-Hodgkin lymphoma or infection. Antiretroviral treatment of patients with incubating,
subclinical tuberculosis may also result in what is called “unmasking IRIS,” where tuberculosis symptoms and clinical manifestations become more pronounced, though whether this
represents normal progression of untreated tuberculosis is not
known [187].
The relative risk of developing IRIS for patients who receive
ART during therapy for tuberculosis is 1.88 (95% CI, 1.31–
2.69), and those who start ART within 2 weeks after starting
Children
Children commonly develop tuberculosis as a complication of
the initial infection with M. tuberculosis ( primary tuberculosis).
The radiographic presentation of primary tuberculosis in children is characterized by intrathoracic lymphadenopathy with or
without lung opacities, occasionally presenting with lymph
node enlargement to a degree that there is compression of airways with or without hyperinflation or collapse of lobe or lung;
breakthrough of node(s) in the airways can manifest with lobar
or segmental infiltration, and a miliary pattern [279, 280]. The
diagnosis of tuberculosis in children is challenging, especially in
young children (<5 years) due to the paucibacillary nature of the
disease. Depending on the setting and resources, diagnosis is
microbiologically confirmed in only 15%–50% of pediatric
cases, and clinical case definitions for tuberculosis in children
have recently been updated [281]. Children, rarely, and adolescents, more frequently, can also develop adult-type tuberculosis
(upper lobe opacities and cavitation associated with sputum
production). The lesions of primary tuberculosis have fewer
M. tuberculosis organisms than those of adult-type pulmonary
tuberculosis; thus, treatment failure, relapse, and development
of secondary resistance are less common events among children
when standard treatment regimens are initiated in a timely
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Immune Reconstitution Inflammatory Syndrome
tuberculosis therapy have higher rates than those who start between 8–12 weeks [261–263]. In general, development of IRIS
does not worsen treatment outcomes for either tuberculosis
or HIV infection, and most episodes can be managed symptomatically. An exception to this is the development of IRIS in patients with CNS tuberculosis, where IRIS may cause severe or
fatal neurological complications. In a study of patients with tuberculosis meningitis and HIV infection, early initiation of ART
(within 2 weeks) was associated with increased rates of adverse
events and higher mortality [278]. Thus, ART is not initiated in
the first 8 weeks of antituberculosis therapy for patients with
HIV infection and tuberculous meningitis (or other CNS tuberculosis), even for patients with CD4 cell counts <50 cells/µL.
Management of IRIS is symptomatic. Based on expert
opinion, for most patients with mild IRIS, tuberculosis and antiretroviral therapies can be continued with the addition of antiinflammatory agents such as ibuprofen. For patients with
worsening pleural effusions or abscesses, drainage may be necessary. For more severe cases of IRIS, treatment with corticosteroids is effective. In a placebo-controlled trial of prednisone for
patients with moderate IRIS, prednisone 1.25 mg/kg/day significantly reduced the need for hospitalization or surgical procedures [70]. For patients who develop IRIS, prednisone may be
given at a dose of 1.25 mg/kg/day (50–80 mg/day) for 2–4
weeks, with tapering over a period of 6–12 weeks or longer.
Controlled trials investigating whether treatment with nonsteroidal anti-inflammatory agents or corticosteroids can prevent
the development of IRIS are under way or in development.
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by weighing or proportioning of the contents that are in turn admixed with food or prepared into a suspension. With the recent
development of child-friendly antituberculosis formulations meeting the dosage guidelines set by the WHO, procedures for making
such improvised formulations should no longer be needed [290].
In the United States, DOT has become the default programmatic approach to treating children with tuberculosis [17].
Based on expert opinion, parents should not supervise DOT
for their children. Even when drugs are administered under
DOT, tolerance of the medications must be monitored closely.
When feasible, daily dosing is preferred by experts [77, 279,
287]; however, twice- or thrice-weekly dosing has also been
endorsed during the continuation phase of treatment for
HIV-uninfected children in settings where DOT is well established [77] (see Supplementary Appendix C and Table 3 for
dosing of antituberculosis drugs in children).
Monitoring response to treatment in children can be challenging because of the difficulties in demonstrating M. tuberculosis in children. Clinical and radiographic worsening may not
be accompanied by positive AFB smears or mycobacterial cultures. According to experts, continued child growth and development while on treatment for tuberculosis usually predicts a
positive outcome of treatment. A decision to modify the drug
regimen should be undertaken with caution. Changes to the
regimen are usually based on clinical and radiographic grounds.
However, experts note that hilar adenopathy and resultant atelectasis in children on occasion can require 1–2 years to resolve;
thus, an improving but persistent abnormality on a chest radiograph in an asymptomatic child is not believed to justify an extension of therapy. If there is concern that poor treatment
response may be due to possible drug-resistant tuberculosis, expert opinion is that the child should be fully reinvestigated, verifying contact history and source case drug susceptibility test
results, as well as obtaining additional specimens for cultures
and drug susceptibility testing.
According to expert opinion, most forms of extrapulmonary
tuberculosis in children can be treated with the same regimens
as pulmonary disease [77, 286]; however, for children with confirmed or suspected tuberculous meningitis or osteoarticular tuberculosis caused by a drug-susceptible organism, expert
opinion is that the duration of the continuation phase should
be extended (See “Tuberculous Meningitis”). For tuberculous
meningitis, the AAP lists an initial 4-drug regimen of INH,
RIF, PZA, and an aminoglycoside or ethionamide for 2 months,
followed by 7–10 months of INH and RIF. For patients who
may have acquired tuberculosis in geographic areas where resistance to streptomycin is common, kanamycin, amikacin, or
capreomycin is used instead of streptomycin [77]. Fluoroquinolones have been studied in adults with tuberculous meningitis
[291], and these studies provide some evidence in support of
their use; however, there have been no published trials of
their use for tuberculous meningitis in children.
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manner. However, it is often more difficult to isolate M. tuberculosis from a child with pulmonary tuberculosis than from an
adult. Therefore, choosing appropriate treatment drugs often
requires the results of specimen culture and drug susceptibility
tests from the person presumed to be the source of the child’s
infection. Based on expert opinion, when drug resistance is suspected or no source-case isolate is available, attempts to isolate
organisms are critical; approaches including obtaining 3 early
morning gastric aspirations (optimally during hospitalization),
sputum induction [282], bronchoalveolar lavage [283], or tissue
biopsy must be considered. Any information gained from molecular and phenotypic tests conducted on these samples is used to
select an individualized regimen for the patient. Because tuberculosis in infants and children <4 years of age is more likely to disseminate and result in subsequent morbidity and mortality,
empiric treatment is started as soon as the diagnosis is suspected,
and particular care is given to drug dosage selection as an important component of achieving adequate concentrations of bactericidal drugs in body fluids, including the cerebrospinal fluid [284].
Several controlled and many observational trials of 6-month
therapy in children with known or presumed drug-susceptible
pulmonary tuberculosis have been published [285]. Based on
systematic reviews of the literature, both the AAP [77] and
the WHO [286, 287], list a 4-drug regimen (INH, RIF, PZA,
and EMB) for 2 months followed by a 2-drug (INH and RIF)
regimen for 4 months as the preferred regimen for children
with suspected or confirmed pulmonary tuberculosis. The
AAP Red Book also states that children who are receiving
EMB should be monitored monthly for visual acuity and redgreen color discrimination if they are old enough to cooperate.
The AAP further notes that the use of EMB in young children
whose visual acuity cannot be monitored requires consideration
of risks and benefits, but it can be used routinely to treat tuberculosis disease in infants and children unless otherwise contraindicated [77]. As an approach to avoiding EMB ocular toxicity,
some clinicians use a 3-drug regimen (INH, RIF, and PZA) in
the initial 2 months of treatment for children who are HIV uninfected, have no prior tuberculosis treatment history, are living
in an area of low prevalence of drug-resistant tuberculosis, and
have no exposure to an individual from an area of high prevalence of drug-resistant tuberculosis. However, because the prevalence of and risk for drug-resistant tuberculosis can be difficult to
ascertain, the AAP and most experts include EMB as part of the
intensive phase regimen for children with tuberculosis. Pyridoxine, 25–50 mg/day, is given to infants, children, and adolescents
undergoing INH treatment if they have nutritional deficiencies,
symptomatic HIV infection, or are breastfeeding. Pyridoxine is
also given to breastfeeding infants of mothers who are receiving
INH [42, 77, 288, 289]. The lack of approved pediatric dosage
forms for most antituberculosis medications has resulted in the
creation and use of improvised formulations. This has entailed
crushing tablets or opening capsules to access the drug, followed
Extrapulmonary Tuberculosis
PICO Question 7: Does the use of adjuvant corticosteroids in
tuberculous pericarditis provide mortality and morbidity benefits?
Recommendation 7: We suggest initial adjunctive corticosteroid
therapy not be routinely used in patients with tuberculous pericarditis
(conditional recommendation; very low certainty in the evidence).
PICO Question 8: Does the use of adjuvant corticosteroids in
tuberculous meningitis provide mortality and morbidity benefits?
Recommendation 8: We recommend initial adjunctive corticosteroid
therapy with dexamethasone or prednisolone tapered over 6–8
weeks for patients with tuberculous meningitis (strong
recommendation; moderate certainty in the evidence).
Lymph Node Tuberculosis
We believe a 6-month regimen is adequate for initial treatment of
all patients with drug-susceptible tuberculous lymphadenitis
[293–298]. Affected lymph nodes may enlarge and new nodes
can appear during or after therapy without any evidence of bacteriological relapse [293, 295, 296, 299]. Therapeutic lymph node
excision is not indicated except in unusual circumstances. For
large lymph nodes that are fluctuant and appear to be about to
drain spontaneously, aspiration has been reported by some experts to be beneficial, although this approach has not been examined systematically. Incision and drainage techniques applied to
cervical lymphadenitis, however, have been reported to be
Bone, Joint, and Spinal Tuberculosis
Six- to 9-month regimens containing RIF for treatment of
bone, joint, and spinal tuberculosis are at least as effective as
18-month regimens that do not contain RIF [302–304]. Because
of the difficulties in assessing response, however, some experts
tend to favor the 9-month duration, and in the setting of extensive orthopedic hardware, some experts extend the duration of
treatment further to 12 months. Several trials found no additional
benefit of surgical debridement in combination with chemotherapy compared with chemotherapy alone for spinal tuberculosis
[80, 303–306]. As such, uncomplicated cases of spinal tuberculosis are managed with medical rather than surgical treatment.
However, based on expert opinion, surgery can be considered
in situations in which (1) there is poor response to chemotherapy
with evidence of ongoing infection or ongoing deterioration; (2)
relief of cord compression is needed in patients with persistence
or recurrence of neurologic deficits; or (3) there is instability of
the spine [307]. Spinal tuberculosis with evidence of meningitis
is managed as tuberculous meningitis, including consideration of
adjunctive corticosteroids (see Tuberculous Meningitis).
Pericardial Tuberculosis
A 6-month regimen is adequate for patients with pericardial tuberculosis. Based on small studies that have shown mortality
and morbidity benefits [71–73], corticosteroids have previously
been universally recommended as adjunctive therapy for tuberculous pericarditis, however, a recent placebo-controlled randomized clinical trial with 1400 participants did not find a
difference in the combined primary endpoint of the trial,
which included mortality, cardiac tamponade, or constrictive
pericarditis, between patients treated with adjunctive corticosteroids vs placebo [74]. A subgroup analysis, however, did suggest
a benefit in preventing constrictive pericarditis. Similarly, a systematic review conducted to obtain evidence in support of this
guideline did not find a statistically significant benefit in terms
of mortality or constrictive pericarditis from the use of corticosteroids (see Supplementary Appendix B, Evidence Profile 14)
[71–75]. Therefore, we suggest that adjunctive corticosteroids
should not be used routinely in the treatment of patients with
pericardial tuberculosis (Recommendation 7: conditional recommendation; very low certainty in the evidence). However, selective use of glucocorticoids in patients who are at the highest
risk for inflammatory complications might be appropriate. Such
patients might include those with large pericardial effusions,
those with high levels of inflammatory cells or markers in pericardial fluid, or those with early signs of constriction [76].
Pleural Tuberculosis
A standard 6-month regimen (Table 2) is also adequate for
treating pleural tuberculosis. Some clinicians consider using
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Tuberculosis can involve virtually any organ or tissue in the
body. The principles underlying the treatment of pulmonary tuberculosis also apply to extrapulmonary disease. Chemotherapy
for extrapulmonary tuberculosis is initiated with INH, RIF,
PZA, and EMB in an initial 2-month phase. After 2 months
of 4-drug therapy, for extrapulmonary tuberculosis known or
presumed to be caused by susceptible strains, PZA and EMB
may be discontinued, and INH and RIF continued during a
continuation phase. Increasing evidence, including randomized
controlled trials, suggests that 6–9 month INH and RIF-containing regimens are effective for the majority of extrapulmonary sites of disease. The exception is tuberculous meningitis
where the optimal duration of therapy has not been established
through randomized controlled trials, but most experts and society guidelines prescribe 12 months of treatment [78, 292]. The
opinion of experts is that the preferred frequency of dosing for
extrapulmonary tuberculosis is once daily for both the intensive
and continuation phases. No randomized controlled trials have
studied intermittent drug administration for extrapulmonary
tuberculosis. If intermittent regimens are used, experts believe
that highly intermittent, once-weekly regimens should be avoided because of insufficient experience with this regimen in extrapulmonary tuberculosis. In regard to treatment monitoring,
bacteriologic evaluation is often limited by the difficulty in obtaining follow-up specimens. Sputum specimens are obtained
when there is concurrent pulmonary involvement, otherwise,
response to treatment in extrapulmonary diseases is often
judged on the basis of clinical and radiographic findings.
associated with prolonged wound discharge and scarring [300].
Of note, the majority of lymphatic cases of mycobacterial disease
in US children are caused by nontuberculous mycobacteria [301].
Tuberculous Meningitis
Tuberculous meningitis remains a potentially devastating disease associated with a high morbidity and mortality in children
and adults, despite prompt initiation of adequate chemotherapy
[314]. HIV-infected individuals appear to be at increased risk
for developing tuberculous meningitis, but the clinical features
of the disease are similar to those in tuberculous meningitis patients without HIV infection [315–317]. High short-term morbidity and mortality is reported regardless of HIV serostatus
[315–317]; however, 9-month survival was further decreased
in HIV-infected patients compared with HIV-uninfected patients in one cohort study [318].
Chemotherapy for tuberculous meningitis is initiated with
INH, RIF, PZA, and EMB in an initial 2-month phase. After
2 months of 4-drug therapy, for meningitis known or presumed
to be caused by susceptible strains, PZA and EMB may be discontinued, and INH and RIF continued for an additional 7–10
months, although the optimal duration of chemotherapy is not
defined. Based on expert opinion, repeated lumbar punctures
should be considered to monitor changes in cerebrospinal
fluid cell count, glucose, and protein, especially early in the
course of therapy. In children with tuberculous meningitis,
the AAP lists an initial 4-drug regimen of INH, RIF, PZA,
and ethionamide or an aminoglycoside for 2 months (in place
of EMB), followed by 7–10 months of INH and RIF [77]. There
are no data from controlled trials to guide the selection of EMB
vs an injectable or ethionamide as the fourth drug for tuberculosis meningitis [78]. Most societies and experts recommend the
use of either an injectable or EMB. For adults, based on expert
opinion, our writing committee prefers using EMB as the fourth
drug. Fluoroquinolones, as well as higher doses of intravenous
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RIF, are being evaluated in adults with tuberculous meningitis
[291, 319]; a large randomized controlled trial
(ISRCTN61649292) is under way to evaluate the impact on reducing mortality of levofloxacin combined with higher-dose rifampicin during the intensive phase of treatment [320]. Selected
complications of tuberculous meningitis warranting neurosurgical referral include hydrocephalus, tuberculous cerebral abscess, and clinical situations in which there is paraparesis [78].
A number of studies have examined the role of adjunctive corticosteroid therapy in the treatment of tuberculous meningitis [79–91]. Our updated systematic review found a
mortality benefit from the use of adjuvant corticosteroids (See
Supplementary Appendix B, Evidence Profile 15). Therefore, we
recommend adjunctive corticosteroid therapy with dexamethasone or prednisolone tapered over 6–8 weeks for patients with
tuberculous meningitis (Recommendation 8: strong recommendation; moderate certainty in the evidence).
Disseminated Tuberculosis
Based on expert opinion, a standard daily 6-month regimen
(Table 2) is adequate for tuberculosis at multiple sites and for
miliary tuberculosis; however, supporting data from controlled
clinical trials are limited. Some experts believe concurrent corticosteroid therapy is indicated for treating severe respiratory
failure or adrenal insufficiency caused by disseminated tuberculosis [321–323], though the role of adjunct corticosteroid treatment in patients with miliary tuberculosis remains unclear
[324]. Patients with disseminated tuberculosis may have concomitant neurologic complications, with indolent symptoms
of CNS involvement, which should be appropriately worked
up [325]. Treatment recommendations for tuberculous meningitis are followed when there is CNS involvement.
Genitourinary Tuberculosis
Renal tuberculosis is treated primarily with medical rather than
surgical therapy, and expert opinion is that a standard daily
6-month regimen (Table 2) is adequate [326–329]. If ureteral
obstruction occurs, procedures to relieve the obstruction are
indicated. In cases of hydronephrosis and progressive renal insufficiency due to obstruction, renal drainage by stenting or
nephrostomy is advised by experts [330]. Nephrectomy is considered when there is a nonfunctioning or poorly functioning
kidney, particularly if hypertension or continuous flank pain
is present. Dose adjustment is required in patients with coexistent renal failure. Tuberculosis of the female or male genital
tract responds well to standard chemotherapy, although surgery
may be indicated for residual, large, tubo-ovarian abscesses.
A positive urine culture for M. tuberculosis is a component of
the diagnostic assessment of genitourinary tuberculosis [331].
A positive urine culture for M. tuberculosis is also sometimes
seen in tuberculosis patients with advanced HIV infection, and
may reflect disseminated disease and/or occult genitourinary
tract involvement. Rarely, a positive culture may occur in the
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adjunctive corticosteroid therapy for tuberculous pleural effusions, and a number of studies have examined the risks and benefits of this approach [308]. Four have been prospective, double
blind, and randomized [309–311], one of which was conducted
in patients with HIV infection [312]. In all 4 studies, prednisone
(or prednisolone) administration did not confer a beneficial effect on residual pleural thickening or prevention of other longterm pleural sequelae. In one study, an increased risk for Kaposi
sarcoma was noted with the use of prednisolone in HIV-associated tuberculous pleurisy [312]. Based on these randomized
clinical trials and a systematic review, there is no evidence to
support the routine use of adjunctive corticosteroids in patients
with tuberculous pleurisy.
Tuberculous empyema, a chronic, active infection of the
pleural space containing a large number of tubercle bacilli, usually occurs when a cavity ruptures into the pleural space. Treatment consists of drainage (often requiring a surgical procedure)
and antituberculous chemotherapy [313]. The optimum duration of treatment for this unusual form of tuberculosis has
not been established.
absence of any abnormalities on urinalysis and does not necessarily represent invasive genitourinary tract involvement [332].
Abdominal Tuberculosis
Expert opinion is that a 6-month regimen is adequate for patients with peritoneal or intestinal tuberculosis [333–335].
The nonspecific presentation of abdominal tuberculosis
means that a high index of suspicion is an important factor
in early diagnosis and initiation of treatment [336, 337]. Data
on adjunctive corticosteroid therapy in the treatment of tuberculous peritonitis are limited [338]; thus, experts believe it
should not be prescribed routinely.
Other Sites of Involvement
Culture-Negative Pulmonary Tuberculosis in Adults
PICO Question 9: Does a shorter duration of treatment have similar
outcomes compared to the standard 6-month treatment duration
among HIV-uninfected patients with paucibacillary tuberculosis (ie,
smear negative, culture negative)?
Recommendation 9: We suggest that a 4-month treatment regimen is
adequate for treatment of HIV-uninfected adult patients with AFB
smear- and culture-negative pulmonary tuberculosis (conditional
recommendation; very low certainty in the evidence).
Failure to isolate M. tuberculosis from appropriately collected
sputum specimens in persons who, because of clinical or radiographic findings, are suspected of having pulmonary tuberculosis does not exclude a diagnosis of active pulmonary
tuberculosis. Some causes of failure to isolate organisms include
the recent use of antibiotics with bactericidal activity against
M. tuberculosis (eg, fluoroquinolones), low bacillary populations, inadequate sputum specimens, temporal variations in
the number of expelled bacilli, overgrowth of cultures with
other microorganisms, and errors in specimen processing
[92]. Alternative diagnoses must be considered and appropriate
diagnostic studies undertaken in patients who appear to have
culture-negative tuberculosis. At a minimum, patients suspected of having pulmonary tuberculosis have 2 sputum specimens
(using sputum induction with hypertonic saline if necessary)
for AFB smears and cultures for mycobacteria or for rapid molecular testing for M. tuberculosis as part of the diagnostic evaluation. Other diagnostic procedures, such as bronchoscopy with
bronchoalveolar lavage and biopsy, are considered before making
a presumptive diagnosis of culture-negative tuberculosis.
Patients who, on the basis of careful clinical and radiographic
evaluation, are thought to have pulmonary tuberculosis should
have treatment initiated with INH, RIF, PZA, and EMB even
when the initial sputum smears are negative. If M. tuberculosis
is isolated in culture or a rapid molecular test is positive,
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As noted above, tuberculosis can involve any organ or tissue.
When treating tuberculosis in sites other than those mentioned,
the basic principles of therapy apply, but experts should be
consulted.
treatment for active disease is continued for a full, standard 6month course (Table 2), if appropriate based on drug susceptibility test results. Patients who have negative cultures but who
still are presumed to have pulmonary tuberculosis should have
thorough clinical and radiographic follow-up after 2 months of
therapy. If there is clinical or radiographic improvement and no
other etiology is identified, treatment should be continued.
The optimum treatment regimens and duration for culturenegative tuberculosis have not been convincingly established.
We performed a systematic review that evaluated 4- and
6-month treatment regimens using available clinical trials
data in adult (>15 years of age) patients. No clinical trials
data on shortened treatments in children were available. A
study from Hong Kong demonstrated that for adults with
smear-negative, culture-positive, and culture-negative pulmonary tuberculosis, a 4-month regimen of INH, RIF, streptomycin, and PZA given either daily or thrice weekly was highly
successful [339]. In Arkansas, a 4-month INH and RIF regimen
for culture-negative tuberculosis was successful with only 1.2%
relapses during an average follow-up of 44 months [340]. In
Singapore, a study of a small number of patients with smearnegative and either culture-positive or culture-negative tuberculosis treated with INH, RIF, and PZA daily for 2 months
followed by INH and RIF either daily or thrice weekly for 2
months showed a high degree of success in both groups [341].
Overall, these 3 studies report a proportion relapsing of only
1.9% among a total of 940 patients treated for 4 months, all
of whom had at least 3 negative smears/cultures prior to starting
therapy. Our systematic review of available clinical trials data in
adult (>15 years of age) patients did not identify a significant
difference in the risk of relapse in culture-negative tuberculosis
treated for either 4 or 6 months (see Supplementary Appendix
B, Evidence Profile 16). Consequently, we suggest that a 4month treatment regimen is adequate for HIV-uninfected
adults with culture-negative pulmonary tuberculosis (conditional recommendation; very low certainty in the evidence). Operationally, treatment is initiated with an intensive phase of INH,
RIF, PZA, and EMB daily and continued in all patients suspected of having pulmonary tuberculosis even when the initial bacteriologic studies are negative. If all cultures on samples deemed
to be adequate are negative and there is clinical or radiographic
response after 2 months of intensive phase therapy, the continuation phase with INH and RIF can be shortened to 2 months.
Clinical and radiographic response, assessed at the end of treatment, is used to determine whether an extension in treatment to
a full standard 6-month regimen is needed. Alternatively, if
there is concern about the adequacy of workup or the accuracy
of the microbiologic evaluations, a standard 6-month regimen
remains preferred (Table 2) [14, 15].
On occasion, patients who are being evaluated for pulmonary
tuberculosis will be found to have positive AFB smears but negative cultures. Potential causes include the possibilities that the
acid-fast organisms are fastidious mycobacteria other than
M. tuberculosis complex, that they are nonviable M. tuberculosis, or that the results are due to laboratory error (false-positive
smear, or false-negative culture). The approach in such cases is
individualized on the basis of clinical and radiographic findings,
as well as the results of rapid molecular diagnostic studies; discussion with the microbiologist performing the cultures is prudent. If clinical suspicion of tuberculosis is high, particularly if
there is clinical and radiologic improvement since the start of
therapy, then therapy is continued for a minimum of 6 months
as for culture-positive pulmonary tuberculosis.
small concentrations of antituberculosis drugs measured in
breast milk have not been reported to produce toxic effects in
the nursing infant [77]. Conversely, drugs in breast milk should
not be considered to serve as effective treatment for active tuberculosis or latent tuberculosis infection in a nursing infant.
Whenever INH is given to a pregnant or nursing woman, supplementary pyridoxine, 25–50 mg/day, is prescribed [42, 43,
357, 358]. According to the AAP, supplementary pyridoxine
(1–2 mg/kg/day) is also prescribed to exclusively breastfed infants, even those not receiving INH [77, 289].
Renal Disease
Pregnancy and Breastfeeding
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Patients with renal insufficiency or end-stage renal disease
(ESRD) are immunocompromised [359]. Tuberculosis patients
with chronic renal failure have worse clinical outcomes than
those without renal failure, and, thus, experts recommend close
monitoring during tuberculosis treatment [360]. The pharmacokinetics of antituberculosis drugs are altered as some are cleared
by the kidneys and/or removed via hemodialysis [361, 362].
Therefore, dose adjustment in patients with renal insufficiency
or ESRD may be required (Table 3 and Table 12). Decreasing
the dose lowers peak serum drug concentrations and can compromise treatment efficacy. Based on expert opinion, the interval
between drug doses in patients with a creatinine clearance of <30
mL/minute and those receiving hemodialysis should be increased
instead. In patients with borderline renal function, a 24-hour
urine collection may be needed to more accurately define the degree of renal insufficiency prior to making regimen changes [242,
363]. Insufficient data exist to guide dosing recommendations for
patients with a reduced but >30 mL/min creatinine clearance. In
such patients, standard doses are used by experts, but measurement of serum concentrations 2 and 6 hours after timed administration can be used to assist with optimizing drug dosages.
RIF and INH are metabolized by the liver, and conventional
dosing can be used in the setting of renal insufficiency. Although
PZA is metabolized by the liver, its metabolites (pyrazinoic acid
and 5-hydroxy-pyrazinoic acid) may accumulate in patients with
renal insufficiency. EMB is approximately 80% cleared by the
kidneys and may accumulate in patients with renal insufficiency.
Experts suggest a longer interval between doses (ie, thrice weekly)
for PZA and EMB [242, 363]. With hemodialysis, PZA and, presumably, its metabolites are cleared to a significant degree, INH
and EMB are cleared to some degree, and RIF is not cleared by
hemodialysis [361]. The fluoroquinolones are also cleared variably by the kidneys. Levofloxacin undergoes greater renal clearance than moxifloxacin [179]. Postdialysis administration of all
antituberculosis medications is preferred to facilitate DOT and
to avoid premature clearance of drugs such as PZA. Monitoring
serum drug concentrations, along with careful clinical and pharmacological assessment, in patients with ESRD, may be necessary. ESRD patients are often taking other medications that
interact with antituberculosis drugs or have comorbid clinical
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Treatment for tuberculosis is initiated whenever the probability of
maternal disease is moderate to high because of the risk of untreated tuberculosis to a pregnant woman and her fetus [342–
345]. Although antituberculosis drugs cross the placenta, they
do not appear to have teratogenic effects in humans [346–349].
However, the inclusion of PZA in the treatment regimen for pregnant women is controversial in the United States. The FDA previously classified all 4 first-line drugs, INH, RIF, PZA, and EMB,
as having equal potential for teratogenicity (all assigned to category C according to the previous FDA letter-based classification
system, which is currently being revised [350]). We suggest that
clinicians evaluate the risks and benefits of prescribing PZA on
a case-by-case basis, allowing the patient to make an informed
and educated decision, recognizing that for all first-line drugs,
risk cannot be ruled out as there are no adequate and wellcontrolled studies in humans, but potential benefits warrant use
of the drug in pregnant women despite potential risks. It is also
important to recognize that PZA has been used extensively in
high-burden countries for many years, and is recommended by
the WHO for tuberculosis in pregnancy, as part of the standard
treatment regimen [98]. Expert opinion is that in pregnant
women with tuberculosis and HIV, extrapulmonary or severe tuberculosis, it is more beneficial to include PZA in the treatment
regimen than to not include PZA. If a decision is made to exclude
PZA from the regimen, a minimum of 9 months of INH, RIF, and
EMB is used for most pregnant women with drug-susceptible tuberculosis. Expert consultation should be sought when first-line
drugs cannot be used due to adverse effects or antibiotic resistance, when there is extensive disease and/or a risk of noncompliance. Although the fetal effects of many second-line drugs are not
well established, small case series of pregnant women treated with
second-line drugs (from studies in drug-resistant tuberculosis)
suggest that good outcomes are achievable and that termination
of the pregnancy is not necessary [351–354]. Overall, the absence
of high-quality studies combined with estimates of >200 000 cases
of tuberculosis in pregnant women each year highlight the need
for additional research in this area [355, 356].
Breastfeeding is encouraged for women who are deemed
noninfectious and are being treated with first-line agents. The
Table 12.
Dosing Recommendations for Adult Patients With Reduced Renal Functiona
Change in Frequency?
Recommended Dose and Frequency for Patients With Creatinine
Clearance <30 mL/min, or Patients Receiving Hemodialysis
Isoniazid
No
300 mg once daily, or 900 mg 3 times/wk
Rifampin
No
600 mg once daily, or 600 mg 3 times/wk
Pyrazinamide
Yes
25–35 mg/kg/dose 3 times/wk (not daily)
Ethambutol
Yes
20–25 mg/kg/dose 3 times/wk (not daily)
Levofloxacin
Yes
750–1000 mg/dose 3 times/wk (not daily)
Drug
Moxifloxacin
No
400 mg once daily
Cycloserine
Yes
250 mg once daily, or 500 mg/dose 3 times/wkb
250–500 mg/dose daily
Ethionamide
No
Para-amino salicylic acid
No
4 g/dose twice daily
Streptomycin
Yes
15 mg/kg/dose 2-3 times/wk (not daily)
Capreomycin
Yes
15 mg/kg/dose 2-3 times/wk (not daily)
Kanamycin
Yes
15 mg/kg/dose 2-3 times/wk (not daily)
Amikacin
Yes
15 mg/kg/dose 2-3 times/wk (not daily)
Standard doses are given unless there is intolerance.
The medications should be given after hemodialysis on the day of hemodialysis.
Monitoring of serum drug concentrations should be considered to ensure adequate drug absorption, without excessive accumulation, and to assist in avoiding toxicity.
Data currently are not available for patients receiving peritoneal dialysis. Until data become available, begin with doses recommended for patients receiving
hemodialysis and verify adequacy of dosing using serum concentration monitoring.
• In patients with 30–50 mL/min creatinine clearance, standard doses are used by experts, but measurement of serum concentrations 2 and 6 hours after timed
administration can be used to assist with optimizing drug dosages.
a
Including adult patients receiving hemodialysis.
b
The appropriateness of 250-mg daily doses has not been established. There should be careful monitoring for evidence of neurotoxicity.
conditions that could affect drug absorption, such as diabetes
mellitus with gastroparesis. For patients receiving peritoneal dialysis, there is currently a paucity of pharmacokinetic and dosing
data, and the dosages in Table 12 may not apply to patients receiving peritoneal dialysis. Such patients may require close monitoring for toxicity, and measurements of the serum
concentrations of antituberculosis drugs before and after peritoneal dialysis should be considered.
Hepatic Disease
Tuberculosis treatment in patients with preexisting advanced
liver disease poses significant challenges. The likelihood of
drug-induced hepatitis is increased with prior advanced liver disease [364], liver transplant [365], or hepatitis C infection [366,
367]. Abnormal baseline aminotransferases alone are an independent risk factor for DILI [364, 368]. Experts recommend that patients with a history of injection drug use, birth in Asia or Africa
(or other hepatitis virus endemic regions), or HIV infection have
hepatitis B and C virus screening at baseline (Table 7). For patients with marginal hepatic reserve, superimposed DILI [56]
may be severe, even life-threatening [369]. Fluctuations of
serum aminotransferases and total bilirubin from preexisting
liver disease can confound monitoring for DILI. Hepatic tuberculosis may also cause elevated aminotransferases, which improve with effective tuberculosis treatment.
Regimens with fewer potentially hepatotoxic agents are selected in patients with advanced liver disease or whose serum ALT is
>3 times the upper limit of normal at baseline (and not thought
to be caused by tuberculosis). The crucial efficacy of INH and
particularly RIF warrant their use and retention, if at all possible,
even in the face of preexisting liver disease. Expert consultation is
advisable. Adjustments during treatment may be necessary. Drug
susceptibility testing to fluoroquinolones and injectables is indicated if use of these drugs is being considered.
Alternative regimens for use in patients with hepatic disease
include:
• Treatment without PZA: PZA has often been implicated in
DILI. A potential regimen could be INH, RIF, and EMB for 2
months, followed by 7 months of INH and RIF [370, 371].
• Treatment without INH and PZA: For advanced liver disease patients, RIF and EMB with a fluoroquinolone, injectable,
or cycloserine for 12–18 months, depending on the extent of the
disease and response could be considered [372].
• Treatment without INH: Based on outcomes of studies on
INH-resistant tuberculosis, a regimen of RIF, PZA, and EMB
with or without a fluoroquinolone could be considered for a
total duration of at least 6 months [373]. Although this regimen
has 2 potentially hepatotoxic medications, it has the advantage
of retaining a treatment duration of 6 months.
• Regimens with little or no potential hepatotoxicity: For
patients with severe, unstable liver disease, EMB combined
with a fluoroquinolone, cycloserine, and second-line injectable
for 18–24 months (similar to an multidrug-resistant tuberculosis regimen) can be considered [374]. Some experts avoid
aminoglycosides in patients with severe, unstable liver disease
due to concerns about renal insufficiency or bleeding from
the site of injected medication due to thrombocytopenia and/
or coagulopathy.
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•
Monitoring of Treatment in Hepatic Disease
Advanced Age
The risk of drug-induced hepatitis and other serious adverse effects increases with advancing age because of less efficient drug
elimination due to reduced renal and hepatic clearance [56]. Because PZA is the most common culprit [378, 379], the benefits
of including PZA in the initial regimen for elderly patients with
modest disease and low risk of drug resistance may be outweighed by the risk of serious adverse events. Consequently,
some experts avoid the use of PZA during the intensive phase
among patients >75 years of age. In such cases, the initial regimen consists of INH, RIF, and EMB. If PZA is not used during
the intensive phase, then the total duration of tuberculosis treatment should be extended to at least 9 months. When the elderly
patient has active tuberculosis with high bacillary burden (ie, bilateral cavitation) and, thus, treatment failure or the development of drug resistance is a concern, benefits and risks of
adding PZA or a fluoroquinolone (eg, levofloxacin, moxifloxacin) vs no fourth drug should be carefully considered. The risk
of drug interaction is increased in the elderly and consideration
may need to be given to dose adjustments or use of alternative
regimens. Careful clinical monitoring to detect intolerance and
adverse reactions is warranted.
Other Comorbid Conditions
As noted previously, the CDC and WHO recommend routine
HIV testing and counseling to all patients with presumptive
and diagnosed tuberculosis [253, 254]. Experts also recommend
that patients with a history of injection drug use, HIV infection,
or birth in Asia or Africa (or other hepatitis virus endemic
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RECURRENT TUBERCULOSIS, TREATMENT
FAILURE, AND DRUG RESISTANCE
Recurrent Tuberculosis
Recurrence refers to the circumstance in which a patient whose
sputa had become and remained culture negative while
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Data to guide the monitoring of patients with preexisting severe
liver disease are scarce. Clinical monitoring and patient education for manifestations of liver injury is warranted for all patients [56]. Experts in the field recommend measuring serum
aminotransferases and total bilirubin concentrations every
1–4 weeks for at least the first 2–3 months of treatment. The
INR may also be periodically followed for patients with severe
hepatic impairment [56, 375, 376]. An increase in serum ALT is
more specific for hepatocellular injury than an increase in AST,
which can also signify abnormalities in muscle, heart, or kidney
[56, 377]. In patients with more advanced preexisting disease,
such as those with cirrhosis or encephalopathy, the ALT thresholds for treatment interruption have not been defined. Some experts recommend, in addition to weekly or twice-weekly ALT
monitoring, interrupting treatment for only a 3-fold elevation
of ALT, even if asymptomatic [375, 376]. Reintroduction of antituberculous treatment may entail rechallenge and/or substitution of agents, while trying to retain the most effective
medications [56]. Whenever feasible, management of tuberculosis in the setting of severe hepatic disease is undertaken in
consultation with experts.
regions) undergo hepatitis B and C virus screening at baseline.
Based on limited data, some experts also suggest screening for
helminthic infections, including malaria, strongyloides, and
schistosomiasis in patients originating from regions hyperendemic for these diseases. In general, tuberculosis treatment for
patients with diseases or conditions that alter immune responsiveness, including HIV infection, parasitic and helminthic infections, hematologic or reticuloendothelial malignancies,
immunosuppressive therapy (eg, TNF-α inhibitors) [380],
chronic renal failure [381], diabetes mellitus, and malnutrition
is based on the standard, daily 6-month regimen (Table 2).
Nonetheless, decisions regarding treatment of comorbidities
and the duration of tuberculosis treatment can be individualized, taking into account disease severity, organs involved,
and response to treatment. For example, based on increased
rates of tuberculosis recurrence, some experts suggest extending
the total duration of tuberculosis treatment to 9 months in
poorly controlled diabetes mellitus [49, 50, 382, 383]. Similarly,
for patients with silicotuberculosis, data demonstrate that cure
rate is improved if the continuation phase is extended by at least
2 months [169, 384]. Based on data suggesting increased mortality with shorter durations of treatment, some experts also
suggest extending the total duration of tuberculosis treatment
to at least 9 months for all solid organ transplant recipients
[385].
The management of immunosuppressive therapy in patients
who develop active tuberculosis varies based on the comorbid
condition. If possible, steps are taken to correct immunodeficiency. In patients with rheumatologic disease, expert opinion
is that TNF-α inhibitor therapy is held if clinically feasible,
when active tuberculosis is suspected or confirmed. There is
no consensus on when TNF-α inhibitor therapy can be resumed. However, small case series suggest that it is safe to resume TNF-α inhibitor therapy in patients who complete at least 2
months of antituberculosis treatment and have a good clinical
response [380, 386, 387]. The decision to restart TNF-α inhibitor treatment should be individualized, taking into account the
clinical need for immunosuppressive therapy, the extent of tuberculosis disease, and clinical response to antituberculosis
treatment. Of note, severe IRIS-like reactions in the setting of
holding TNF-α inhibitor treatment have been reported [388].
In solid organ transplant recipients, significant pharmacological
interactions can occur between rifamycin-based antituberculosis regimens ( particularly RIF) and calcineurin inhibitors or rapamycin; on this basis, strict monitoring of serum drug
concentrations is needed to prevent rejection [389].
consists of the standard intensive phase regimen of daily INH,
RIF, PZA, and EMB, plus a later-generation fluoroquinolone,
an injectable, and depending on the severity of disease or the anticipated extensiveness of resistance, an additional second-line
drug [404]. All drugs are administered using DOT. An expanded
regimen is indicated especially in patients with impaired immunity, limited respiratory reserve, CNS involvement, other lifethreatening circumstances, or any other situation in which treatment with an inadequate regimen could have severe consequences to the individual or the community.
When epidemiological circumstances render exogenous reinfection the most likely cause of apparent relapse, the regimen
choice is influenced by the drug susceptibility pattern of the
presumed source case and/or drug-resistance testing. If the presumed source case is known to have drug-resistant organisms,
an expanded empiric regimen based on the resistance profile of
the putative source case may be suitable.
Poor Treatment Response and Treatment Failure
In the United States, treatment failure is defined as continuously
or recurrently positive cultures after 4 months (5 months in
Europe and WHO guidelines [98]) of treatment in a patient receiving appropriate chemotherapy. Among patients with drugsusceptible pulmonary tuberculosis, even with extensive lung
cavitation, 90%–95% will be culture negative after 3 months
of treatment with a regimen that contains INH and RIF. During
this time, the vast majority of patients show clinical improvement, including reduced fever, reduced cough, and weight
gain. Thus, patients with persistently positive cultures after 3
months of chemotherapy, with or without ongoing symptoms,
are evaluated carefully to identify the cause of delayed response.
Multiple reasons for poor treatment response and treatment
failure exist. For patients not receiving DOT, one explanation
may be nonadherence to the treatment regimen. Among patients receiving DOT, cryptic nonadherence (spitting out or deliberately regurgitating tablets or capsules) or failure of the
healthcare system to reliably deliver the drugs may be a cause.
Other potential reasons include unrecognized drug resistance
(drug susceptibility testing not done, misreported, or misinterpreted; reinfection with a drug-resistant strain), malabsorption
(diarrhea, or prior resection surgery of the stomach or small intestine, or taking tuberculosis medications with antacids or
other drugs/substances that might bind or interfere with drug
absorption), or diabetes mellitus with or without gastroparesis
[198, 199, 201, 405–410]. Some experts use TDM to evaluate
poor drug exposure as a contributing factor to treatment failure
[242]. Laboratory error (eg, cross-contamination or mislabeling
of specimens) is also a possible reason for a positive culture in a
patient who is doing well clinically [411].
Clinicians should be alert, as well, to the possibility of transient clinical or radiographic worsening ( paradoxical reactions),
despite appropriate therapy that would eventually result in cure.
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receiving antituberculosis drugs becomes culture positive or experiences clinical or radiographic deterioration consistent with
active tuberculosis after completion of therapy. In such patients,
vigorous efforts are made to establish a diagnosis and to obtain
microbiologic confirmation of the relapse to enable testing for
drug resistance. True relapses, defined as recurrent tuberculosis
caused by the same strain as was identified at baseline, are
thought to be due to failure of chemotherapy to sterilize the
host tissues, thereby enabling endogenous recrudescence of
the original infection. In high-incidence settings or where infection control is poor, however, exogenous reinfection with a new
strain of M. tuberculosis may be responsible for the apparent recurrence (in this context, not referred to as relapse) [390, 391].
Patients at risk for relapses are those with extensive disease at
baseline and whose sputum cultures remain positive after completion of the intensive phase of treatment [9, 392]. However, the sensitivity of culture-positive status at 2 months for predicting relapse
is low [46]. Most relapses occur within the first 6–12 months after
completion of therapy [393]. In the majority of patients with tuberculosis caused by drug-susceptible organisms who were treated
by DOT with rifamycin-containing regimens, relapses occur with
susceptible organisms [394, 395]. However, the risk of acquired
drug resistance is substantial in patients who have a relapse
after receiving SAT, a highly intermittent regimen in the setting
of HIV infection, a non-rifamycin-containing regimen (including
receiving only INH and EMB in the continuation phase of treatment), or a second-course of a first-line regimen reinforced by
streptomycin [59, 60, 396–400]. In addition, if initial drug susceptibility testing was not performed and the patient fails or relapses
with a rifamycin-containing regimen using DOT, a high likelihood exists that the organisms were resistant from the outset
[399, 401, 402]. To help guide regimen selection, rapid molecular
tests have been used at the time of suspected recurrence as an approach to rapidly identifying the presence of resistance-conferring
mutations; however, the detection of M. tuberculosis DNA and
RIF resistance have been reported as being false positive [403]. Experts suggest caution in interpreting results from molecular tests
used at the time of suspected recurrence.
The selection of empiric treatment regimens for patients with
relapses is based on the prior treatment scheme. For patients with
relapse who were treated for drug-susceptible tuberculosis using
DOT, experts recommend retreatment using the standard intensive phase regimen until the results of susceptibility tests are
known. For patients who did not receive DOT or had irregular
treatment, it is prudent to infer a higher risk of acquired drug resistance. Whenever feasible, rapid molecular and phenotypic diagnostics for detection of drug resistance should be used to
inform regimen selection. When immediate treatment initiation
is necessary, consider the use of an expanded empiric regimen in
consultation with experts in the treatment of drug-resistant disease. If started, an expanded empiric regimen is administered
until the results of susceptibility tests are known and commonly
Tuberculosis Caused by Drug-Resistant Organisms
Mycobacterium tuberculosis bacilli are continually undergoing
spontaneous mutations that create resistance to individual antituberculosis drugs; however, the frequency of these mutations is sufficiently low that with appropriate combination chemotherapy
that is reliably ingested, clinically significant resistance is very unlikely to develop [121, 414]. Acquired drug resistance can occur,
however, when there is a large bacillary population (such as in
pulmonary cavities), an inadequate drug regimen, a combined
failure of both the patient and the provider to ensure that an adequate regimen is ingested, or malabsorption of one or more antituberculosis drugs [415, 416]. During extended or repeated
treatment, amplification of resistance to multiple agents may
occur. Patients with acquired drug resistance may transmit their
strains to others who, if they develop tuberculosis, will have primary drug resistance. Notable clinical and demographic risk factors for drug-resistant tuberculosis include having a previous
episode of tuberculosis treatment (in particular if the regimen
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was inadequate or adherence to the regimen was low), originating
from or living for an extended period in a country with a high
prevalence of drug-resistant tuberculosis, and having a history
of exposure to an index case with drug-resistant tuberculosis.
Comprehensive guidance on the management of drugresistant tuberculosis is beyond the scope of this document,
though international guidelines exist [404]. An ATS/CDC/
ERS/IDSA practice guideline for the management of drugresistant tuberculosis is also currently under development
using GRADE methodology.
RESEARCH AGENDA FOR TUBERCULOSIS
TREATMENT
Much progress has been made over the last 10 years in the treatment of tuberculosis [109, 417]. The corpus of knowledge on
new drug combinations, drug interaction with antiretrovirals,
methods of dosing, and timing of dosing is increasing. Based
on the writing of this guideline, however, several priority
areas in need of additional research were identified.
New Antituberculosis Drugs and Regimens
Treatment of tuberculosis remains centered around the same
6-month, 4-drug regimen introduced >40 years ago. The identification of more potent drugs and drug regimens that permit
shortening the duration of treatment remains a key priority.
A number of new drugs and regimens for tuberculosis are currently being investigated in clinical trials. This includes repurposed drugs (eg, daily high-dose RPT and higher dosages of
RIF, linezolid and carbapenems) and new drugs (eg, bedaquiline, delamanid, and pretomanid [formerly PA-824]). Highdose, daily RPT is being tested in a treatment-shortening
phase 3 clinical trial, with dosage selected based on dose-ranging, drug-exposure optimization studies (ClinicalTrials.gov
identifier: NCT02410772) [418]. Pretomanid is being tested as
part of a combination regimen including moxifloxacin and PZA
for the treatment of both drug-susceptible and drug-resistant
tuberculosis (ClinicalTrials.gov identifier: NCT02193776). Bedaquiline, approved by the US FDA for treatment of multidrug-resistant tuberculosis in 2012, is also being investigated
in drug-susceptible disease as part of a combination regimen including pretomanid and PZA and/or clofazimine in a phase 2
study (ClinicalTrials.gov identifier: NCT01691534). Broadly,
the tuberculosis therapeutics development field would greatly
benefit from dose-ranging and drug–drug interaction studies
for new and existing drugs so as to identify the drug exposures
and optimal combinations necessary to achieve maximal efficacy, while improving safety and tolerability.
Biomarkers of Treatment Effect and Individualization of Therapy
The success of therapy depends upon many diverse factors and
only some are presently predictable, identifiable, or modifiable.
Inclusion of biomarker substudies that assess both microbial
and host biomarkers within phase 3 clinical trials will yield
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Examples of this include ongoing inflammation at sites of
lymphadenitis, worsened abnormalities on chest radiographs
after several months of treatment, or the new appearance of
pleural effusions during therapy for pulmonary tuberculosis.
Such paradoxical worsening during treatment can occur in
HIV-uninfected patients, as well as in HIV-infected patients
(see “Immune Reconstitution Inflammatory Syndrome”). The
diagnosis of a paradoxical reaction is made only after a thorough evaluation has excluded other etiologies, particularly tuberculosis treatment failure and drug resistance.
For patients who meet criteria for treatment failure, the possible reasons listed above should be addressed promptly. Recent
mycobacterial isolates should be sent to a reference laboratory
for susceptibility testing to both first-and second-line drugs.
If clinicians are not familiar with the management of drugresistant tuberculosis, immediate referral to, or consultation
with a specialty center is indicated. If treatment failure is presumably due to drug resistance and the patient is seriously ill
or has a positive sputum AFB smear, an empiric regimen is
started immediately and continued until susceptibility tests
are available to guide therapy; however, if the patient’s clinical
presentation is not severe, one may either initiate an empiric retreatment regimen or wait for drug susceptibility results from a
recent isolate. Of note, patients who are not on the correct regimen remain infectious [102, 412].
A single new drug is never to be added to a failing regimen as
it can lead to amplification of drug resistance, including acquired resistance to the newly added drug [413]. To lessen the
likelihood of increasing resistance, it is generally prudent to add
2–3 new drugs to which susceptibility could logically be inferred
(eg, using regional drug-resistance surveillance data and the patient’s history of medication use). When drug susceptibility results are available, the regimen is adjusted accordingly.
important knowledge on the factors that impact therapeutic success. Additionally, data on pharmacokinetic/pharmacodynamic
properties that influence drug safety and efficacy, data on drug
penetration and distribution, and the pursuit of sensitive and specific biomarkers that can reliably predict relapse will be critically
important to advancing the tuberculosis therapeutics field [116,
418, 419]. New biomarkers of treatment effect that can be implemented in the field and accurately monitor response to treatment
on an individual basis may also allow for the individualization of
the duration of treatment [420]. However, a considerable increase
in investment in fundamental research is needed to develop and
validate biomarkers of durable cure [421].
adherence rates as in-person DOT [131]. Research to improve
tuberculosis treatment delivery strategies should be informed
by behavioral studies and/or implementation science frameworks, which have been shown to increase the likelihood of
identifying successful multifaceted individual behavior change
and health system interventions. Finally, research on the optimal introduction of new drugs is needed (even after approval
from regulatory bodies) provide data that will facilitate key
implementation decisions around programmatic feasibility,
cost-effectiveness, and optimal approaches to surveillance of
drug resistance and prevention of emergence of new drug resistance [425].
Treatment of Tuberculosis in Special Situations
Supplementary Data
Implementation Research
Even as new drugs and new regimens are being developed, there
remains a critical need to improve the delivery of tuberculosis
treatment. DOT has been the dominant mode of treatment delivery, but evidence supporting its use has been weak. Strategies
that are more convenient for patients and less resource-intensive for public health programs should be further explored
[424]. For example, in low-incidence countries, early studies
have shown that video DOT using smartphones is feasible,
has high patient uptake, and is associated with similar
Supplementary materials are available at http://cid.oxfordjournals.org.
Consisting of data provided by the author to benefit the reader, the posted
materials are not copyedited and are the sole responsibility of the author, so
questions or comments should be addressed to the author.
Notes
Acknowledgments. Our sincerest gratitude for the support provided by
Kevin Wilson, MD (Chief, Documents and Patient Education, American
Thoracic Society); Judy Corn (Director, Documents and Patient Education,
American Thoracic Society); Jennifer Padberg (Director of Clinical Affairs,
Infectious Diseases Society of America [IDSA]); and Phil LoBue, MD (Director of the Division of Tuberculosis Elimination, Centers for Disease Control and Prevention [CDC]) in the development of this guideline.
Guideline Writing Committee Chairs, Members, And Methodologists.
Guideline Committee Chairs: Payam Nahid, MD, MPH, University of
California, San Francisco (Chair, American Thoracic Society); Susan
E. Dorman, MD, Johns Hopkins University, Maryland (Chair, IDSA); Giovanni Battista Migliori, MD, World Health Organization (WHO) Collaborating Centre for TB and Lung Diseases, Fondazione S. Maugeri Care and
Research Institute, Tradate, Italy (Chair, European Respiratory Society); Andrew Vernon, MD, MHS, Division of Tuberculosis Elimination, National
Center for Human Immunodeficiency Virus (HIV)/AIDS, Viral Hepatitis,
Sexually Transmitted Disease (STD), and TB Prevention, CDC, Georgia
(Chair, CDC).
Writing Committee Members. Narges Alipanah, MD, University of California, San Francisco; Pennan Barry, MD, MPH, California Department of
Public Health; Jan Brozek, MD, PhD, McMaster University, Ontario, Canada; Adithya Cattamanchi, MD, MAS, University of California,
San Francisco; Lelia Chaisson, MSc, University of California,
San Francisco; Richard Chaisson, MD, Johns Hopkins University, Maryland; Charles L. Daley, MD, National Jewish Health, Colorado; Susan
E. Dorman, MD, Johns Hopkins University, Maryland; Malgosia Grzemska,
MD, PhD, World Health Organization, Geneva, Switzerland; Julie Higashi,
MD, San Francisco Department of Public Health, TB Control, California;
Christine S. Ho, MD, Division of Tuberculosis Elimination, National Center
for HIV, STD, and TB Prevention, CDC, Georgia; Philip Hopewell, MD,
University of California, San Francisco; Salmaan A. Keshavjee, MD, PhD,
Harvard Medical School, Massachusetts; Christian Lienhardt, MD, PhD,
World Health Organization, Geneva, Switzerland; Richard Menzies, MD,
McGill University, Quebec, Canada; Cynthia Merrifield, RN, University of
California, San Francisco; Giovanni Battista Migliori, MD, WHO Collaborating Centre for TB and Lung Diseases, Fondazione S. Maugeri Care and
Research Institute, Tradate, Italy; Payam Nahid, MD, MPH, University of
California, San Francisco; Masahiro Narita, MD, Seattle and King County
TB Control and University of Washington; Rick O’Brien, MD, Ethics Advisory Group, International Union against TB and Lung Disease, Paris,
France; Charles Peloquin, Pharm. D., University of Florida; Ann Raftery,
RN, PHN, MS, University of California, San Francisco; Jussi Saukkonen,
MD, Boston University, Massachusetts; H. Simon Schaaf, MD, Department
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Based on the writing of this guideline, the need for additional
research was notable for treatment of tuberculosis in special situations. In particular, there is a paucity of high-quality studies
on tuberculosis in pregnant women, breastfeeding women, and
children. A recent US National Institutes of Health convened
workshop examining the inclusion of pregnant and postpartum
women in tuberculosis drug trials has provided consensus statements to help accelerate research in this area [422]. The lack of
pediatric dosage forms of most antituberculosis medications has
up to now necessitated using crushed tablets or opening capsules and creating suspensions to facilitate dosing in young children, and additionally has hampered inclusion of children in
drug trials. As a result of key partnerships and concerted investments in pediatric therapeutics research, an affordable, highquality, child-friendly fixed-dose combination meeting WHO
quality assurance metrics is now being produced; however,
these products are not yet registered in the United States or
Europe [290]. Broadly, to address the paucity of data on the
optimal treatment of children with tuberculosis, the drug development field should design trials to be more inclusive of children as study participants across key stages of therapeutics
research, from pharmacokinetic studies through to phase 3 clinical trials. Examples of ongoing tuberculosis treatment trials
that enroll children and adolescents are the SHINE study
(Shorter Treatment for Minimal TB in Children Study;
ISRCTN63579542), and TBTC Study 31/ACTG A5349 (Rifapentine-Containing Tuberculosis Treatment Shortening Regimens; NCT02410772) [423].
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of Paediatrics and Child Health, Stellenbosch University, Cape Town, South
Africa; Giovanni Sotgiu, MD, PhD, University of Sassari, Sassari, Italy; Jeffrey R. Starke, MD, Baylor College of Medicine, Texas; Andrew Vernon,
MD, MHS, Division of Tuberculosis Elimination, National Center for
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GRADE Methodology Group. Narges Alipanah, MD, University of
California, San Francisco; Jan Brozek, MD, PhD, McMaster University,
Ontario, Canada; Adithya Cattamanchi, MD, MAS, University of California,
San Francisco; Lelia Chaisson, MSc, University of California, San Francisco;
Richard Menzies, MD, McGill University, Quebec, Canada; Payam Nahid,
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Financial support. Support for this guideline was provided by the
American Thoracic Society, the IDSA, and the CDC.
Potential conflicts of interest. The authors have reported to the American Thoracic Society the following: P. M. B. reported that his spouse previously owned stocks or options of Merck. R. E. C. reported service as a
consultant and ownership of stocks or options for Merck. C. L. D. received
research support from Insmed and served on data and safety monitoring
boards of Otsuka America Pharmaceutical and Sanofi Pasteur. C. A. P. received research support from Jacobus Pharmaceuticals. J. S. reported service
on a data safety and monitoring board of Otsuka Pharmaceuticals. A. V. reported serving as the chief of a CDC clinical research branch doing clinical
trials in tuberculosis, which supports and works with the TB Trials Consortium (TBTC) that collaborates with pharmaceutical companies, which may
provide support such as drug supplies or laboratory funding for pharmacokinetic substudies. Specifically, Sanofi Aventis has provided approximately
$2.8 million in unrestricted grants to the CDC Foundation to facilitate or
support TBTC work related to rifapentine, including contract research
staff, pharmacokinetic substudies, travel to TBTC scientific meetings for invited speakers, and expenses related to fulfillment of company requests for
data and data formats as part of use of TBTC data in support of regulatory
filings. TBTC has studies under way involving rifapentine and levofloxacin
that may have relevance for future regimens for drug-susceptible tuberculosis and for multidrug-resistant tuberculosis. All other authors report no potential conflicts. All authors have submitted the ICMJE Form for Disclosure
of Potential Conflicts of Interest. Conflicts that the editors consider relevant
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Official ATS/CDC/IDSA Clinical Practice Guidelines: Treatment of Drug-Susceptible
Tuberculosis (Nahid et al, CID 2016)
APPENDIX C:
DRUGS IN CURRENT USE
The U.S. Food and Drug Administration (FDA) has approved 11 drugs for treating tuberculosis. Several other
drugs, including levofloxacin and moxifloxacin, are not FDA approved for tuberculosis, but are used in selected
populations. Rifabutin, approved for disseminated Mycobacterium avium complex disease, can be used to
minimize drug-drug interactions. Amikacin and kanamycin are aminoglycosides used for drug-resistant
organisms. Clofazimine, linezolid, and selected beta-lactam – beta-lactamase inhibitor combinations have
been used in patients with drug resistant tuberculosis. The precise role of these additional drugs in the
treatment of tuberculosis is a subject for further research.
Isoniazid (INH), rifampin (RIF), pyrazinamide (PZA), and ethambutol (EMB) are considered first-line
antituberculosis agents and form the core of initial treatment regimens. Rifabutin (RBT) and rifapentine (RPT)
also may be used under certain circumstances. RBT is used predominantly to minimize drug interactions, as
the current available evidence does not otherwise support the replacement of RIF by RBT for first-line
treatment of tuberculosis [432]. RPT is currently used for latent tuberculosis infection, and may have an
increasing role in the management of drug-susceptible tuberculosis pending ongoing randomized clinical trials.
INH has excellent early bactericidal activity (EBA, meaning it is capable of causing a rapid drop in the number
of actively multiplying bacilli within days), while rifamycins and PZA have excellent sterilizing activity,
functioning to prevent post-treatment relapses). Streptomycin currently is seldom used. The remaining drugs
are reserved for special situations, such as drug intolerance or mycobacterial resistance.
Basic antimicrobial pharmacology is predicated upon achieving adequate drug exposure. This exposure
generally is quantified as the area under the curve (AUC) in a plot of unbound (protein-free, f) serum drug
concentration versus time divided by the minimal inhibitory concentration (MIC) (i.e., the fAUC/MIC). For
certain antimicrobials, peak concentration (fCmax/MIC) or time above MIC (f%Time>MIC) are more predictive
of efficacy in the models or the patients studied. When fAUC/MIC or fCmax/MIC are most predictive of
microbial killing, antimicrobials are considered “concentration-dependent.” Otherwise, when time above MIC
(f%Time>MIC) is they are considered “time-dependent.” The use of such pharmacokinetic / pharmacodynamic
(PK/PD) data allow for the most effective employment of antimicrobials, achieving maximum pathogen killing in
the shortest time possible. Historically, these measures of drug effect have not been quantified routinely in
tuberculosis patients. Drug exposure (i.e., AUC) has been assumed to be “adequate” in all treated patients,
regardless of their weight or condition, and this has led to some uncertainties in terms of optimal dosing of firstline drugs. Instead of an MIC, isolates only have been characterized as “susceptible or resistant” at a “critical
concentration”. In some locations, susceptibility data have not been used at all. Therefore, clinicians generally
have not known how close serum drug concentrations were to achieving sub-MIC exposures in their patients.
Even with weight adjustment, optimal dosing of PZA, for example, has yet to be determined. In prior guidance,
PZA was recommended at 20 mg/kg/day (20-25 mg/kg/day); international guidelines recommend 25 mg/kg/day
(20-30 mg/kg), however, the British Medical Research Council (BMRC) short-course clinical trials used PZA at
36 mg/kg/day [433-436]. Further research is needed to establish the optimal dosing of PZA in terms of
efficacy, safety and tolerability.
Drug exposure is determined by the magnitude and the frequency of the dose. Drug exposure also is
determined by the size of the patient, and the patient’s ability to clear the drug through the liver and/or kidneys.
Inadequate drug exposure has been shown to produce delayed treatment responses and failures, as well as
drug resistance [9, 249]. Conversely, high drug exposures have been correlated with more rapid clearance of
tuberculosis [418]. Thus, drug exposure is a key driver of efficacy in tuberculosis patients, and fixed doses
(INH 300 mg, RIF 600 mg) and “maximum” doses may not be appropriate for heavier patients. This document
removes the term “maximum” dose.
Isoniazid (INH)
• Role in treatment regimen: INH is a first-line agent for treatment of all forms of tuberculosis caused by
organisms known or presumed to be susceptible to the drug. It has strong early bactericidal activity
against rapidly dividing organisms [105, 437].
• Dose: (See Table 2).
o Adults: typically 300 mg daily, or 15 mg/kg (typically 900 mg) once, twice, or three times weekly.
o Children: 10-15 mg/kg daily; 20-30 mg/kg twice weekly.
• Preparations: Tablets (50 mg, 100 mg, 300 mg); Syrup (50 mg/5 ml); Aqueous solution (100 mg/ml) for
intravenous or intramuscular injection.
• Adverse effects:
o Asymptomatic elevation of aminotransferases: Aminotransferase elevations up to 5 times the
upper limit of normal occur in 10-20% of persons receiving INH alone for treatment of latent
tuberculosis infection [438]. The enzyme concentrations usually do not continue to rise or return
to normal even with continued administration of the drug, a phenomenon known as hepatic
adaptation.
o Clinical hepatitis: Hepatitis occurred in 0.1-0.15% of 11,141 persons receiving INH alone as
treatment for latent tuberculosis infection in an urban tuberculosis control program [439]. A
meta-analysis of 6 studies estimated the rate of clinical hepatitis with INH alone to be 0.6%, with
INH administered with other agents not including RIF to be 1.6%, and when INH was given with
RIF to be 2.7% [187]. For INH alone the risk increases with increasing age; it is uncommon in
persons under 20 but is nearly 2% in persons aged 50-64 [440]. The risk increases in persons
with underlying liver disease, including viral hepatitis; current heavy alcohol consumption;
concomitantly taking hepatotoxic medications, and possibly in postpartum women [441].
o Fatal hepatitis: Once estimated to be as high as 14 per 100,000 [155], more recent studies
suggest the rate of fatal hepatitis is substantially lower, between 1 and 7 per 100,000 [442-444].
Death and liver failure have been associated with continued administration of INH after the
onset of symptoms of hepatitis [445].
o Peripheral neuropathy [357, 446]: This adverse effect is dose-related and is uncommon (<0.2%)
at conventional doses in otherwise healthy persons [447, 448]. The risk is increased in persons
with nutritional deficiency, diabetes, HIV infection, renal failure, and alcoholism, as well as for
pregnant and breastfeeding women and for those on certain chemotherapies [288]. Pyridoxine
supplementation (25-50 mg/day) is used to minimize risk of neuropathy [42] and is used by
some experts at higher doses (100 mg/day) to treat symptoms of peripheral neuropathy.
o Central nervous system effects: Effects such as headaches, dysarthria, irritability, seizures,
dysphoria, depression, and inability to concentrate have been reported.
o Lupus-like syndrome [449, 450]: Approximately 20% of patients receiving INH develop
antinuclear antibodies. Less than 1% develops clinical lupus erythematosis, necessitating drug
discontinuation [451].
o Hypersensitivity reactions: Reactions, such as fever, rash, Stevens-Johnson syndrome,
hemolytic anemia, vasculitis, and neutropenia are rare.
o Monoamine (histamine/tyramine) poisoning: This rare event produces headaches, flushing,
lightheadedness, after consuming foods and drinks (certain cheeses and wine), having high
concentrations of monoamines [218, 452-454].
o Diarrhea: The commercial liquid preparation of INH contains sorbitol and may cause diarrhea.
•
•
•
•
•
Use in pregnancy: There are no adequate and well-controlled studies in pregnant women. According to
previous FDA classification systems (currently under revision [350]) and drug package inserts, the
potential teratogenic effects of INH are assigned to a Category C risk (Risk not ruled out, but potential
benefits may warrant use of the drug in pregnant women despite potential risks). Based on extensive
use, INH is considered safe in pregnancy, even in the setting of HIV-coinfection [455, 456], but the risk
of hepatitis has been reported to be increased in the peripartum period [441]. In pregnant patients,
pyridoxine supplementation (25-50 mg/day) is used [42].
CNS penetration: Penetration is excellent: cerebrospinal fluid (CSF) concentrations are similar to
concentrations achieved in serum [457, 458].
Use in renal disease: INH can be used safely without dose adjustment in patients with renal
insufficiency [459] and with end-stage renal disease patients who require chronic hemodialysis (see
Guideline Section on Renal Disease) [361, 460].
Use in hepatic disease: Drug accumulation may occur in advanced hepatic disease. INH may be
considered in patients with stable hepatic disease with frequent laboratory and clinical monitoring (see
Guideline Section on Hepatic Disease).
Monitoring: Routine monitoring generally is not done. However, in patients with pre-existing liver
disease or who develop abnormal liver function that does not require discontinuation, liver function tests
and symptoms are closely monitored. Serum concentrations of phenytoin and carbamazepine may be
increased in people taking INH without RIF, and monitoring is required.
Rifampin (RIF)
• Role in treatment regimen: RIF is a first-line agent for treatment of all forms of RIF-susceptible
tuberculosis. It has substantial sterilizing activity [461]. RIF is an essential component of all shortcourse regimens.
• Dose: (See Table 2)
o Adults: typically 600 mg once daily, or with careful patient selection, twice weekly, or three times
weekly. Higher daily doses are being studied.
o Children: 10-20 mg/kg once daily or twice weekly
• Preparations: Capsules (150 mg, 300 mg) contents of capsule may also be mixed into an oral
suspension; aqueous solution for parenteral administration.
• Adverse effects [462, 463]:[464]
o Cutaneous reactions [465]: Pruritis with or without rash (6% of patients) is generally self-limited
[466]. Continued treatment may be possible. More severe, true hypersensitivity reactions occur
in 0.07-0.3% of patients [447, 467, 468].
o Gastrointestinal reactions (nausea, anorexia, abdominal pain): Incidence is variable but rarely
severe enough to require discontinuation [463, 465, 466].
o Flu-like syndrome: Historically seen with intermittent high dose administration (900mg or higher
administered intermittently) [465, 469, 470]. This reaction is uncommon with daily dosing [6,
467, 468].
o Hepatotoxicity Transient asymptomatic hyperbilirubinemia may occur [56]. Clinical hepatitis with
a cholestatic pattern also may occur [187, 471]. Hepatitis is more common when combined with
INH (2.7%) [187].
o Severe immunologic reactions: In addition to cutaneous reactions and flu-like syndrome, other
reactions thought to be immune mediated include the following: thrombocytopenia, hemolytic
anemia, acute renal failure, and thrombotic thrombocytopenic purpura [472-474]. These
reactions are rare, each occurring in <0.1% of patients [467, 468]. RIF must be permanently
discontinued in the setting of severe immunologic reactions.
o Orange discoloration of bodily fluids (sputum, urine, sweat, tears): Patients should be warned of
this effect. Soft contact lenses and clothing may be permanently stained.
Drug interactions due to induction of hepatic microsomal enzymes: RIF is a major cause of drug
interactions (see Section on Drug-Drug Interactions) with potentially serious consequences.
Affected drugs include oral contraceptives, methadone, and warfarin. Readers are advised to
consult the CDC website http://www.cdc.gov/tb/default.htm to obtain the most up-to-date
information.
o False-positive opiate results: RIF can cause false-positive immunoassay results for urine
opiates [475].
Use in pregnancy: There are no adequate and well-controlled studies in pregnant women. According to
previous FDA classification systems (currently under revision [350]) and drug package inserts, the
potential teratogenic effects of RIF are assigned to a Category C risk (Risk not ruled out, but potential
benefits may warrant use of the drug in pregnant women despite potential risks). Based on extensive
use, RIF is considered safe in pregnancy [476].
CNS penetration: Concentrations in the CSF may be only 10-20% of serum concentrations. Higher
doses of RIF may be more effective [77, 477, 478].
Use in renal disease: RIF can be used safely without dose adjustment in patients with renal
insufficiency and end-stage renal disease (see Guideline Section on Renal Disease) [361, 478].
Use in hepatic disease: Reduced RIF clearance may occur with advanced liver disease [478]. Other
than in settings of advanced liver disease, RIF generally can be used safely, with increased frequency
of clinical and laboratory monitoring (see Guideline Section on Hepatic Disease).
Monitoring: No routine monitoring tests are required. Drug interactions may necessitate therapeutic
concentration monitoring of other drugs.
o
•
•
•
•
•
Rifabutin (RFB)
• Role in treatment regimen: RFB generally is reserved for patients who are receiving any medication
having unacceptable interactions with RIF (e.g., select antiretroviral therapies) or have experienced
intolerance to RIF. The replacement of rifampicin by rifabutin for first-line treatment of tuberculosis is
otherwise not supported by current evidence [432].
• Dose: (See Table 2)
o Adults: typically 300 mg daily. With concomitant use of boosted protease inhibitors (i.e. with
ritonavir or cobicistat), a starting dose of 150 mg daily. With efavirenz, RFB is increased to 450600 mg daily. See http://www.cdc.gov/tb/publications/guidelines/HIV_AIDS.htm to obtain the
most up-to-date information.
o Children: Pediatric doses are not established. Serum concentrations can direct dosing. 5 mg per
kg may be a reasonable starting dose.
• Preparations: Capsules (150 mg) for oral administration.
• Adverse effects:
o Hematologic toxicity: Neutropenia and thrombocytopenia may occur in patients receiving RFB
[479-481].
o Uveitis: This is rare (<0.01%) in the absence of drug-interactions. Rates are higher when RFB is
combined with inhibitors of CYP3A4 (macrolides, azoles, ritonavir or cobicistat) that reduce
clearance of RFB and its 25-desacetyl metabolite [195, 480, 482, 483].
o Gastrointestinal symptoms: GI symptoms may occur, as with RIF.
o Polyarthralgias: This symptom may occur [484].
o Hepatotoxity: At the usual doses (150–300 mg/day), hepatotoxicity is uncommon [56].
Asymptomatic elevation of liver enzymes has been reported with high-dose rifabutin treatment
in combination with macrolides [195].
o Pseudo-jaundice (skin discoloration with normal bilirubin): This is usually self-limited and
resolves with discontinuation of the drug [482].
Rash: Only rarely associated with RFB. Acute generalized exanthematous pustulosis (AGEP)
has been reported with RFB [485].
o Flu-like syndrome: Flu-like syndrome is rare in patients taking RFB.
o Orange discoloration of bodily fluids (sputum, urine, sweat, tears): Patients should be warned of
this effect. Soft contact lenses and clothing may be permanently stained.
Use in pregnancy: There are no adequate and well-controlled studies in pregnant women. According to
previous FDA classification systems (currently under revision [350]) and drug package inserts, the
potential teratogenic effects of RFB are assigned to a Category B risk (Risk not ruled out, but potential
benefits may warrant use of the drug in pregnant women despite potential risks). In rats and rabbits,
RFB used at 6 to 13 times the recommended human daily dose based on body surface area
comparisons, no teratogenicity was observed [486].
CNS Penetration: The drug has variable penetration of inflamed meninges, based largely on animal
model and very limited clinical data [487-489].
Use in renal disease: RFB may be used without dosage adjustment in patients with renal insufficiency
and end-stage renal disease (see Guideline Section on Renal Disease) [490, 491].
Use in hepatic disease: Reduced RFB clearance may occur with advanced liver disease
[490][427][408]. Increase the frequency of clinical and laboratory monitoring when using RFB (or other
rifamycin) in the setting of hepatic disease (see Guideline Section on Hepatic Disease).
Monitoring: No routine monitoring tests are required. Two-way drug interactions may necessitate
therapeutic concentration monitoring of RFB and the other drugs.
o
•
•
•
•
•
Rifapentine (RPT)
• Role in treatment: Previously, RPT was approved for use once-weekly, with INH, in the continuation
phase of treatment for HIV-seronegative patients with noncavitary, drug-susceptible pulmonary
tuberculosis who have negative sputum smears at completion of the intensive phase of treatment [9]. A
6-month regimen in which in the two-month intensive phase, INH is replaced by daily moxifloxacin
400mg followed by one weekly dose of both moxifloxacin 400mg and 1200 mg of RPT for 4 months in
the continuation phase, has also been investigated in one clinical trial for pulmonary tuberculosis [163].
• Dose: (See Table 2)
o Adults: Previously 10 mg/kg (typically 600 mg) once weekly during the continuation phase of
treatment. Currently, 900 mg RPT once weekly (with INH 900 mg) has been approved for latent
tuberculosis infection. Additionally, daily doses of 1200mg of RPT daily are being evaluated for
active tuberculosis disease (ClinicalTrials.gov Identifier: NCT02410772).
o Children: The drug is being studied in children. Proportionally higher doses (up to 2 times the
adult mg per kg dose) may be needed.
• Preparation: Tablet (150 mg film coated).
• Adverse effects: The adverse effects of RPT are similar to those associated with RIF. Like RIF, RPT is
a strong inducer of multiple hepatic enzymes and may cause drug-interactions. (see Section on DrugDrug Interactions).
• Use in pregnancy: There are no adequate and well-controlled trials of RPT in pregnant women.
According to previous FDA classification systems (currently under revision [350]) and drug package
inserts, the potential teratogenic effects of RPT are assigned to a Category C risk (Risk not ruled out,
but potential benefits may warrant use of the drug in pregnant women despite potential risks).
• CNS penetration: Insufficient information.
• Use in renal disease: Like RIF, RPT shows minimal renal clearance and thus likely can be used safely
without dose adjustment in patients with renal insufficiency and end-stage renal disease (see
Guideline Section on Renal Disease).
•
•
Use in hepatic disease: Reduced RPT clearance may occur with advanced liver disease. Increase the
frequency of clinical and laboratory monitoring when using RFB (or other rifamycin) in the setting of
hepatic disease (see Guideline Section on Hepatic Disease).
Monitoring: Monitoring is similar to that for RIF. Drug interactions involving RPT are comparable to
those of RIF.
Pyrazinamide (PZA)
• Role in treatment regimen: PZA is a first-line agent for all PZA-susceptible isolates of tuberculosis. The
drug is believed to exert greatest activity against dormant or semi-dormant organisms in an acidic
environment [98, 492].
• Dose: (see Tables 2, 9)
o Adults: typically 25 mg/kg daily (20-30 mg/kg); 35 mg/kg thrice weekly (30-40 mg/kg); 50 mg/kg
twice weekly. The BMRC original short-course regimen clinical trials used PZA at 36 mg/kg/day
[433-436].
o Children: 30-40 mg/kg daily; 50 mg/kg twice weekly.
• Preparations: 500 mg (scored) tablets.
• Adverse effects:
o Hepatotoxicity: PZA has been identified as the most hepatotoxic of the first line drugs [378].
Early studies using doses of 50-70 mg/kg/day reported high rates of hepatotoxicity [493, 494].
However, liver toxicity was less common at doses of 30-40 mg/kg/day in the BMRC shortcourse clinical trials. Both dose related and idiosyncratic hepatotoxicity may occur [56, 495].
o Gastrointestinal symptoms (nausea, vomiting): Mild anorexia and nausea are common, severe
nausea and vomiting are uncommon [496].
o Non-gouty polyarthralgia: Polyarthralgias may occur in up to 40% of patients receiving PZA, not
requiring discontinuation [497]. Pain usually responds to non-steroidal anti-inflammatory agents.
o Asymptomatic hyperuricemia: This is expected [6, 498, 499], and even can assist in monitoring
patient adherence.
o Acute gouty arthritis: Acute gout is rare [499, 500], except in patients with pre-existing gout
[501]; in patients with severe gout, the decision to use PZA is made in consultation with
tuberculosis experts.
o Transient morbiliform rash: This usually is self-limited, with continuation of the drug.
o Dermatitis: PZA may cause cutaneous adverse drug reactions as well as photosensitive
dermatitis [496, 502-505].
• Use in pregnancy: There are no adequate and well-controlled studies in pregnant women. According to
previous FDA classification systems (currently under revision [350]) and drug package inserts, the
potential teratogenic effects of PZA are assigned to a Category C risk (Risk not ruled out, but potential
benefits may warrant use of the drug in pregnant women despite potential risks). The World Health
Organization has included PZA in the regimen for pregnant women in their tuberculosis treatment
guidelines since the first edition in 1993 [97].
• CNS penetration: The drug passes freely into the CSF [506]. In seven studies recording CSF
concentrations of PZA, concentrations appear satisfactory and comparable to those in blood [458].
• Use in renal disease: PZA is cleared primarily by the liver, but its metabolites are excreted in the urine
and may accumulate in patients with renal insufficiency [507]. The daily dose may be given three times
a week following dialysis in patients with end stage renal disease (Table 11) (see Guideline Section
on Renal Disease) [361].
• Use in hepatic disease: PZA can cause liver injury that may be severe and prolonged. If PZA is used in
patients with liver disease, laboratory and clinical monitoring is increased and expert consultation
sought (see Guideline Section on Hepatic Disease).
•
Monitoring: Routine serum uric acid measurements are not necessary but may serve as a marker for
adherence. Liver chemistry monitoring is performed when the drug is used in patients at risk for, or with
pre-existing, liver disease.
Ethambutol (EMB)
• Role in treatment regimen: EMB is a first line drug used to treat all forms of tuberculosis and prevent
emergence of RIF resistance when primary resistance to INH may be present.
• Dose: (see Tables 2, 10)
o Adults: Recent guidelines have recommended 15-20 mg/kg/day. However, the BMRC original
short-course regimen clinical trials used 25 mg per kg daily [436, 508]. Doses of 20-25 mg/kg
may be appropriate (refs). Table 10 lists recommended dosages for adults, using whole tablets.
o Children: (Table 2): 20 mg/kg/day (15-25 mg/kg); 50 mg/kg twice weekly. The drug can be used
safely in children, including pre-verbal children, with appropriate caution (see Adverse effects
below).
• Preparations: Tablets (100 mg; 400 mg) for oral administration
• Adverse effects:
o Optic (retrobulbar) neuritis: Rarely, decreased visual acuity or decreased red/green color
discrimination that may affect one or both eyes can occur [509]. The risk is higher with higher
daily doses (>27.5 mg/kg/day) [189], prolonged duration of therapy (range 2-9 months) [189191], and in patients with renal insufficiency who accumulate EMB [510]. Higher doses can be
given safely two or three times weekly. Risk factors include age, hypertension, renal failure and
HIV [191, 511, 512]. With appropriate caution, experts believe that EMB can be used safely in
children, including pre-verbal children whose visual acuity cannot be monitored.
o Peripheral neuritis: This is rare [513].
o Cutaneous reactions: Skin reactions requiring discontinuation of the drug occur in 0.2-0.7% of
patients [514].
• Use in pregnancy: There are no adequate and well-controlled studies in pregnant women. According to
previous FDA classification systems (currently under revision [350]) and drug package inserts, the
potential teratogenic effects of EMB are assigned to a Category C risk (Risk not ruled out, but potential
benefits may warrant use of the drug in pregnant women despite potential risks). Based on extensive
use, EMB is considered safe for use in pregnancy [342, 515, 516].
• CNS penetration: The agent penetrates meninges variably in the presence of inflammation but does not
have demonstrated efficacy in tuberculous meningitis [458, 517].
• Use in renal disease: EMB is cleared primarily by the kidneys. The dosing interval may be increased
when creatinine clearance decreases (especially less than 30 ml/min), although a single ml/min
clearance cut-off may not be appropriate for all patients [510, 518]. Therapeutic drug monitoring can be
considered in such patients in order to avoid under- or overdosing [241]. EMB is administered at a dose
of 20-25 mg/kg 3 times a week by DOT after dialysis in patients with end-stage renal disease (Table
11) (see Guideline Section on Renal Disease) [361].
• Use in hepatic disease: EMB can be used safely in patients with hepatic disease (see Guideline
Section on Hepatic Disease).
• Monitoring: While receiving EMB, patients have baseline visual acuity testing (Snellen chart) and
testing of color discrimination (Ishihara Color Test). At each monthly visit patients should be questioned
regarding possible visual disturbances including blurred vision or scotomata. Monthly testing of visual
acuity (Snellen chart) and color discrimination (Ishihara plates) in the clinic is simple to do and is
advisable; such monitoring is essential for any patient with renal insufficiency. Patients should be
instructed to contact their physician or public health clinic immediately if they experience a change in
vision. EMB should be discontinued immediately and permanently if there are any signs of visual
toxicity.
Fixed-dose combination (FDC) preparations
• Role in treatment regimen: Two combined preparations, INH and RIF (Rifamate) and INH, RIF and
PZA (Rifater), are available in the U.S. These formulations are a means of minimizing inadvertent
monotherapy (which increases risk for acquired drug resistance), particularly when DOT is not possible
[174, 175, 177, 519]. The use of FDC formulations also reduces the number of tablets or capsules that
must be taken daily. Constituent drugs are combined in proportions compatible with daily treatment
regimens. Formulations for intermittent administration are not available in the U.S.
o Preparations and Dose: Rifamate: As sold in North America, each capsule contains RIF 300
mg and INH 150 mg, thus, the daily dose is 2 capsules (600 mg RIF and 300 mg INH). Two
capsules of Rifamate plus two 300 mg tablets of INH are used by some programs for
intermittent therapy given twice weekly as DOT. Rifater: Each tablet contains RIF, 120 mg,
INH, 50 mg, and PZA, 300 mg. The daily dose is based on weight as follows: <44 kg - 4 tablets;
45-54 kg - 5 tablets; >55 kg - 6 tablets. To obtain an adequate dose of PZA in people weighing
more than 90 kg additional PZA tablets must be given.
• Adverse effects: Information provided under individual drugs above.
Fluoroquinolones
• Role in treatment regimen: Of the available fluoroquinolones, levofloxacin and moxifloxacin have the
most activity against M. tuberculosis. Cross-resistance has been demonstrated among ciprofloxacin,
ofloxacin, and levofloxacin and presumably is a class effect. Fluoroquinolones are not considered firstline agents for the treatment of drug-susceptible tuberculosis, except in patients who are intolerant of
first-line drugs.
• Dose: (Table 2).
o Adults: Levofloxacin 750-1000 mg daily; moxifloxacin 400 mg daily. Higher doses of levofloxacin
are being studied (ClinicalTrials.gov Identifier: NCT01918397).
o Children: Most experts agree that fluoroquinolones can be considered for children with MDR
tuberculosis. Limited data suggest that levofloxacin doses of 15 mg per kg may be appropriate.
Pediatric doses of moxifloxacin have not been established.
• Preparations: Levofloxacin - tablets (250 mg, 500 mg, 750 mg); aqueous solution (500 mg) for
intravenous administration. Moxifloxacin - tablets 400 mg; aqueous solution (400 mg) for intravenous
administration
• Adverse effects: In general, a similar pattern of adverse effects is seen with levofloxacin and
moxifloxacin. Moxifloxacin carries the greatest risk of QT prolongation as compared to other available
fluoroquinolones in clinical practice [520]. By itself, moxifloxacin rarely is associated with cardiac
dysrhythmias. However, in combination with other drugs that prolong QTc interval (bedaquiline,
delamanid, and clofazimine are some examples) this may be of greater concern, and may require
monitoring.
o Gastrointestinal disturbance: Nausea, anorexia, vomiting, abdominal pain, diarrhea, and taste
disturbance have been reported [521].
o Neurologic effects: Dizziness, insomnia, tremulousness, and headache occur in 1-2% of
patients [521].
o Cutaneous reactions: Rash, pruritis, and photosensitivity have been reported. Levofloxacin and
moxifloxacin have lower potential for phototoxicity than other available fluoroquinolones [521].
o Arthropathy and tendinopathy: Arthropathy, fluoroquinolone-associated tendinitis and tendon
rupture are uncommon, reported at 0.5 and 0.6 cases/100,000 antibiotic treatments in
levofloxacin and moxifloxacin, respectively [521, 522]. Tuberculosis trials evaluating
moxifloxacin have not reported any episodes of tendinopathy or arthropathy [5, 163]. Although
there is a paucity of data, observational studies of children treated with fluoroquinolones for up
•
•
•
•
•
•
to 12 months do not demonstrate any serious arthropathy or other severe musculoskeletal
adverse events in the pediatric population [523-525].
Use in pregnancy: There are no adequate and well-controlled studies in pregnant women. According to
previous FDA classification systems (currently under revision [350]) and drug package inserts, the
potential teratogenic effects of levofloxacin and moxifloxacin are assigned to a Category C risk (Risk
not ruled out, but potential benefits may warrant use of the drug in pregnant women despite potential
risks). Registry data do not reveal any clear adverse reactions (fetal and neonatal toxicity, including
birth defects) due to in-utero exposure to fluoroquinolones [526].
CNS penetration: The concentration in the CSF after administration of a standard dose of levofloxacin
is lower than that in serum [178]. Cerebrospinal fluid penetration, measured by the ratio of the plasma
area under the concentration-time curve from 0 to 24 h (AUC0–24) to the cerebrospinal fluid AUC0–24,
is greater for levofloxacin (median, 0.74; range, 0.58 to 1.03) than for gatifloxacin (median, 0.48; range,
0.47 to 0.50) or ciprofloxacin (median, 0.26; range, 0.11 to 0.77) [291, 458].
Interference with absorption: Antacids and other medications containing divalent cations markedly
decrease the absorption of the fluoroquinolones. Fluoroquinolones should be administered first and a
minimum of 2-3 hours interval (ideally longer) should be provided before use of products containing
divalent cations. Examples of products that decrease absorption of the fluoroquinolones include any
medications containing aluminum, magnesium, calcium, zinc, iron; selected dietary supplements (e.g.
Sustacal, Ensure); and vitamins that also contain minerals.
Use in renal disease: Levofloxacin is cleared primarily (>85%) by the kidney [178]. Dosage adjustment
(750-1000mg 3 times a week) is recommended if creatinine clearance is <30 ml/min (Table 11). Based
on studies in conditions other than tuberculosis, levofloxacin is removed by intermittent hemodialysis,
however, at a lower total clearance compared with healthy subjects [527, 528]. Moxifloxacin is cleared
both hepatically and renally. Typically, dose adjustment of moxifloxacin is not needed in renal
dysfunction (see Guideline Section on Renal Disease).
Use in hepatic disease: Levofloxacin and moxifloxacin plasma concentrations are not affected by
hepatic disease [529]. Levofloxacin and moxifloxacin have been used in the setting of liver disease,
including when hepatotoxicity is attributed to antituberculosis drugs [530], however, when used, routine
monitoring of liver enzymes is recommended (see Guideline Section on Hepatic Disease).
Monitoring: No specific monitoring is recommended.
References:
Please see Official ATS/CDC/IDSA Clinical Practice Guidelines: Treatment of Drug-Susceptible Tuberculosis
document for full references for citations listed in Appendix C.
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